Surface Finishing

1. Surface Finishing Presented By Bidve M.A.

2. Grinding Machines • Grinding is a metal cutting operation which is performed by means of a rotating abrasive wheel acts as a cutting tool. • Material removal is in the form of chips by the mechanical action of abrasive particles bonded together in a grinding wheel.

3. Advantages & Applications ofGrinding Advantages: • Extremely smooth surface finish • High accuracy • Complex profile machining • Hard heat treated material surface finishing • Easy chip removal Applications: • Rough grinding • Finish grinding • Resharpening of cutting tools

4. Classification of Grinding • Non precision grinding machines • Floor stand and bench grinder • Portable and flexible shaft grinder • Swing frame grinder • Abrasive belt grinder • Precision grinding machines • External/internal cylindrical grinders • Surface grinders • Form grinders

5. Cylindrical grinders • Centre type(plain) • Centre type(universal) • Centreless grinder • Surface grinders • Horizontal spindle reciprocating table • Vertical spindle reciprocating table • Horizontal spindle rotary table • Vertical spindle rotary table

6. Centreless grinders • Through feed grinders • In feed grinders • End feed grinders • Internal grinder • Chucking grinder • Planetary grinder • Centreless grinder

7. According to specialized applications • Tool and cutter grinder • Form grinder • Hand grinder • Crankshaft grinder • Thread grinder • Cam grinder

8. Surface grinding machine • Horizontal spindle with reciprocating table • Horizontal spindle with rotary table • Vertical spindle with reciprocating table • Vertical spindle with rotary table

9. Horizontal spindle with reciprocating table • It consist of horizontal spindle located horizontally to mount grinding wheel while the table reciprocates with a mounted work piece • Reciprocating motion of the table provides longitudinal feed and cross feed is provided by the spindle • For taking depth of cut, grinding wheel can be fed downwards, this is called infeed • The amount of feed is very small about 0.005 to 0.15mm

10. Horizontal spindle with rotary table • It is used for facing circular work and narrow rings. • Work is clamped on rotary table and grinding wheel is mounted on horizontal spindle. • The table is made to rotate in a direction opposite to that of the rotation of the grinding wheel • The vertical feed is given by moving the wheel head along the column and cross feed by the horizontal movement of wheel spindle • The work table can be lowered or raised to accommodate different height work piece.

11. Vertical spindle with reciprocating table • It is also known as planer type grinding machine • Grinding wheel spindle is vertical • Work is clamped on reciprocating table and grinding is performed by the face of the wheel • Infeed and cross feed is given by movement of spindle • In these machines, cuped, cylindrical or segmental grinding wheels are used. • The grinding area is large and large quantity of material is removed.

12. Vertical spindle with rotary table • Grinding wheel is mounted on vertical spindle • The work is mounted on table with clamping arrangement or having magnetic chuck • The table rotates in opposite direction to that of wheel • Infeed and cross feed is given by movement of spindle • This type of machine gives higher production rates and comparatively surface finish is not good

13. Cylindrical grinding machine • It is used to produce a cylindrical or conical shape on a work piece by passing the face of grinding wheel • The work piece is mounted between the centres or chuck which is rotated and moved against the rotating wheel • There are four movements are involved • The work revolve about its own axis • Wheel revolve about its own axis • The wheel pass the work through feed • The work pass the wheel through feed

14. Centerless type grinding machine • When the work piece is not supported by the centres but between grinding wheel by a work rest blade, it is called as centreless grinding. • This eliminates the use of work holding devices. Also there is no need to centre the work piece.

15. The wheels are revolving in the identical direction. This revolution of the wheel lead to forced the workpiece on the rest table which is against the control wheel. • The control wheel regulates the speed of the workpiece and running lengthwise feed movement. • The work rest is axially not coincident with axes of workpiece centre, grinding wheel and the control wheel

16. Centre and Centreless Grinding

17. Methods of feed in centreless grinding Through feed grinding: • It is used for straight cylindrical work such as rollers, pins and straight long bars. • Regulating wheel and grinding wheel is adjusted equal to the desired diameter of the work piece. • The job is fed and passed through the gap between the grinding wheel and regulating wheel usually with guides at both ends

18. Infeed grinding: • It is used for grinding headed, stepped parts • The work piece is placed on rest blade and it is moved against the grinding wheel with required feed. • The work rest for this operation does not have guides but adjustable stop is provided at the end.

19. End feed grinding: • It is used for short tapers, here both the wheels have the form corresponding to the shape of the work piece. • The work piece is fed longitudinally from the sides of the wheels • As it advances between the revolving wheels, its surface is ground till its farther end touches the end stop.

20. Specification/Designation/Marking Scheme • It differs with the manufacturer and country. • In order to bring the uniformity, Bureau of Indian Standards has suggested the marking scheme consisting of following six characters is sequence.

21. Prefix: Any prefix can be use by manufacturer to indicate his own trade brand of abrasive used and it is optional. • Abrasive type: Natural abrasives: minerals, diamond, corundum, emery, sand stone or quartz. Main element of corundum and emery is Al2O3 Artificial abrasives: A-Al2O3, S- Silicon carbide • Abrasive grains: It indicates the size of abrasive used for making a grinding wheel. • It may be classified as per the number of openings per square inch such as coarse, medium, fine, very fine.

22. Coarse: 6-24 • Medium: 30-60 • Fine: 70-180 • Very fine: 220-1200 Grade: It is the degree of hardness of the wheel i.e. hardness with which the bond holds the abrasive grains in a place. It is classified as Soft(A-H), Medium(I-P), Hard(Q-Z) Structure: It is the type of spacing of the abrasive grains in which the abrasive grains are distributed throughout the wheel. It is denoted by the number of cutting edges per unit area. Dense(1-8), Open( 9-15 & above)

23. Nature of Bond: It is the type of adhesive grains to form the grinding wheel. Types: Vitrified bond(V), Silicate bond(S), Shellac bond(E), Resinoid bond(B), Rubber bond(R) Manufacturers Symbol: It is also optional, may use suitable suffix to the type of bond. Example: 51 A 36 L 5 V 40 Ans: 51- Manufacturers symbol indicating type of abrasive A- Abrasive( Aluminium oxide) 36- Grain size( medium) L- Grade(medium) 5- Structure Dense V- Bond(Vitrified) 40- Manufacturer Symbol ( suffix) optional

24. Methods to remove the defects in grinding wheel • Trueing: Due to continuous use of the grinding wheel, the cutting points of the abrasive grains becomes dull and it is called glazing. It is the operation to remove the glazing from the grinding wheel. It is carried out with a diamond tool. In this operation, grinding wheel is rotated and diamond tool is held against the wheel. The tool is reciprocated over the wheel to cover the complete width of the wheel

25. 2. Dressing: The cut particles of the material may get adhere to the open space between the cutting points. Due to this the sharpness of the cutting part is lost, the face becomes smooth and losses its cutting ability. This is called the loading of the grinding wheel. Dressing removes the loading defect. It is carried out by the wheel which consists of star tooth cutters mounted on the circumference of the wheel. The wheel is moved against the revolving wheel to dress the surface of the wheel.

26. Selection Criteria/ Factors for Grinding Wheel • Constant factors: • Work piece material • Amount of stock to be removed • Area of contact • Type of grinding machine • Variables factors: • Wheel speed • Work speed • Condition and capacity of machine • Personal factor

27. Balancing of Grinding Wheel • A wheel is said to be unbalanced when some portion of it is heavier whereas the outer is lighter. An unbalanced wheel greatly affect the surface finish and accuracy of the work. To obtain the good surface finish, prevent vibration and undue wear of grinding machine parts, grinding wheel must be good balanced. Unbalanced may cause the wheel break with the chances of damage to the machine and seriously injury to the operator

28. Methods of Balancing Wheel 1. Static Balancing: The wheel is taken off from the grinding machine. The wheel is mounted at the centre of a perfectly straight and round spindle. The assembly is then rested on a know edge balancing stand. Any out of balance will result in the wheel coming to test with the heavy side at the bottom. Correct weight then can be stuck on the opposite side to balance the wheel.

29. Dynamic Balancing: This is done on the machine itself. There is no need to remove the wheel from the machine. It is the proper alignment of the grinding wheel with the shaft on which it is rotating.

30. Safety Precautions • Use of the right wheel. • Test the wheel before use. • Use mounting blotters. • Enough tightening of flange bolts. • Do not exceed maximum speed. • Use safety glasses.

31. Super Finishing • To reduce wear of the machine parts, friction between the machine parts and to give the corrosion resistance properties, fatigue strength, good appearance require the high degree of surface finish of the parts. • But the parts produced by the other machining processes like turning, boring, milling, shaping, drilling does not have the high degree of surface finish. • Honning • Lapping • Polishing • Buffing • burnishing

32. Honning • It is a abrasive finishing operation where a small amount of material is removed from the internal or external surface of a part to improve the surface finish. • It is used to correct the roundness, taper, tool marks and axial distortion. • Mostly honning is done on internal cylindrical surfaces such as automobile cylinder walls, cylinders of IC engines, hydraulic cylinders, gas barrels, bearing, etc. • The abrasive stone used in this process are called as hones, hence the process is known as honning. • Accuracy -0.005mm up to 50mm diameter and 0.01mm for 50-150mm diameter. • Surface finish-0.075microns

33. Honning Tool & its Stone • Honning stones are made from common abrasive and bonding materials often mixed with sulphur, resin, or wax to improve cutting action and lengthen tool life. • Common abrasives are aluminum oxide, silicon carbide, diamond or cubic boron nitride • The abrasive grain size ranges from 80-600 grit

34. Principle of Honning • It is wet cutting process which removes metal from the work piece by means of revolving tool which also reciprocates up and down usually inside the work piece.

35. Honning Set-up and Working • It consist of i) Honning tool ii) Tool movement arrangement iii) machine spindle. • During honning operation, the spindle of the honning machine rotates the hone and simultaneously reciprocates it in a work piece • The spindle speed is generally 2m/s for rotation and 0.5m/s for reciprocating motion. • Coolants are essential for this operation to flush away small chips and to keep temperature uniform.

36. Advantages of Honning • Can remove as little as 0.0025mm of stock. • Work piece need not be rotated. • No chucks, face plates or rotating tables are needed. • It can be done on most of materials from aluminum or brass to hardened steel. • Several holes may be honned simultaneously on multispindlehonning machines.

37. Disadvantages of Honning • Horizontal boring creates oval holes. • Honning stone wear out fast. • Comparatively slow process. • Difficult to process the slim or less thickness parts Applications: • Internal honning- Engine cylinders, gun barrels, long tubular parts. • External honning- Gear teeth, valve seating, races of roller and ball bearings, piston rods, piston pins, shafts.

38. Lapping • It is a precision finishing process where resistance to wear of moving parts and better sealing characteristics is important. • It gives very high degree of accuracy and smoothness • The basic purpose of lapping is to minimize the extremely minute irregularities left on work piece after machining.

39. Principle/ Set-up/ Working • Abrasive powder is assorted with oil or special fixative with exporter are used in lapping. • Lap which is made up of soft material to receive and retain the abrasive grains. Soft material may be like soft cast iron, brass, copper, lead or soft steel is also used in lapping process. • First charging of lap is done. Charging of lap means to embed the abrasive grains into its surface. Hence the face of the lap becomes charged with abrasive particles. • The lap once excited, it should be used without rub in more abrasive until it come to a close to cut the material.

40. Advantages • Any hard or soft material can be lapped • No burrs are created. • Any size from 12 to 900mm diameter can be lapped. • No warping of lapped components. • Disadvantages • Skill and experience is needed for better result • Optimum result can not be ensured.

41. Applications • Press work dies • Moulds for casting • Limit gauges • Slip gauges • Surface plate • Piston rings • Crank shaft • Engine valve and valve seat • Races of ball and roller bearings

42. Polishing • It is a surface finishing operation performed by a improving wheel to remove the tool scripts, abrasion from the workpiece. • The wheels are made of fleece, papers, opus or wool. • The grains are mounted on the face of the wheel. • It is done after grinding and is followed by buffing. • The purpose of polishing is to remove scratches, tool marks, other defects due to machining operation and improves the surface finish.

43. Principle of Polishing • In this process the work is held in hand or on the machine table and the rotating polishing wheel is brought in contact with the work piece surfaces. • An abrasive belt(endless) with very fine grade abrasives may also be used instead of polishing wheels. This belt rotates continuously on two rollers and the work piece to be polished is hand held over this rotating belt. • So in both cases very thin layer is removed from the work piece. • Depending on the number of pieces to be polished, the polishing may be done by hand or machine i.e. hand polishing & machine polishing.

44. Advantages: • No chips formation • Gives mirror type finish • Disadvantages: • Dimensional accuracy is not maintained • Narrow grooves, complex shapes are difficult to polish • Applications: • Polishing of small hand tools • Jet engine turbine blades • Sole plates of electric iron • Parts of fountain pen

45. Buffing • It is a finishing operation usually performed after polishing. • It gives much higher lustrous and reflective surface finish that can not be obtained by polishing. • It removes negligible amount of material. • It is like a polishing operation in which the work piece is brought in contact with a buffing wheel. • Buffing wheels are made of number of layers of cloth or fibre firmly sewed together in thick sections. These layers are closely fasten together by the flanges and mounted on the buffing machine arbor. • The buffing wheel cloth is charged with very fine abrasives with the help of some binders. • The diameter of the wheel is around 300 to 750mm

46. Principle/ Setup and Working • The buffing wheel is rotated at high speed and workpiece to be buffed is made to rub against the charged wheel. • The abrasive removes the minute amount of material from the work piece, removes fine scratches and give high reflective surface finish.

47. Advantges: • Suitable for ferrous and non ferrous • No surface preparation is required. • Disadvantages: 1. Does not maintain flatness/roundness • Appliations: • Automobile, motor cycle and bicycle parts • Household utensils and appliances • Sport items, tools, furniture, fixtures.

48. Burnishing • It is a cold working process by which improvement in surface finish, dimensional accuracy and work hardening is done without removing the metal. • It is non-cutting operation and uses no abrasives. • It is finishing operation and is normally done on parts which are turned, bored, milled, shaped, reamed or ground. • It involves the physical displacement of surface irregularities rather than cutting or grinding. • This process is used for flat, cylindrical and conical surfaces.

49. Principle/Setup/Working • All the machined surface consist of a series of peaks and valleys( surface irregularities) of irregular height and spacing. • The plastic deformation created by burnishing is a displacement of the material from the peaks which cold flows under pressure into the valleys. • This is done by using burnishing tool which consist of tapered rollers mounted on tool holder in a retaining cage.

50. It consist of i) tool holder ii) drill press iii) work piece table • The drill press vertical spindle is used to mount the tool holder and work piece is clamped on machine table with suitable clamping method. • The tool is selected slightly larger than the work piece and allow to pass through it. • While passing on the workpiece, slight pressure gets created that exceeds the yield point of softer part surface. • This result in a small plastic deformation of the surface structure of the work piece. • It produces accurately sized part with a mirror like finish and a tough, work hardened, wear and corrosion resistant surface.