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Turning Operations L a t h e.

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Presentation on theme: "Turning Operations L a t h e."— Presentation transcript:

1 Turning Operations L a t h e

2 Turning Operations Machine Tool – LATHE
Job (workpiece) – rotary motion Tool – linear motions “Mother of Machine Tools “ Cylindrical and flat surfaces

3 Some Typical Lathe Jobs
Turning/Drilling/Grooving/ Threading/Knurling/Facing...

4 The Lathe

5 The Lathe Head Stock Tail Stock Bed Feed/Lead Screw Carriage

6 Main Parts Bed Headstock Feed and lead screws Carriage Tailstock

7 Lathe Bed Heavy, rugged casting Made to support working parts of lathe
On top section are machined ways Guide and align major parts of lathe

8 Lathe Bed

9 Headstock Clamped on left-hand end of bed Headstock spindle
Hollow cylindrical shaft supported by bearings Provides drive through gears to work-holding devices Live center, faceplate, or chuck fitted to spindle nose to hold and drive work Driven by stepped pulley or transmission gears Feed reverse lever Reverses rotation of feed rod and lead screw

10 Headstock

11 Headstock Back Gear arrangement Headstock belt drive

12 Quick-Change Gearbox Contains number of different-size gears
Provides feed rod and lead-screw with various speeds for turning and thread-cutting operations Feed rod advances carriage when automatic feed lever engaged Lead screw advances the carriage for thread-cutting operations when split-nut lever engaged

13 Quick-Change Gearbox

14 Carriage Used to move cutting tool along lathe bed
Consists of three main parts Saddle H-shaped casting mounted on top of lathe ways, provides means of mounting cross-slide and apron Cross-slide Apron

15 Carriage < Saddle < Apron

16 Carriage

17 Carriage

18 Apron The apron attached to the front of the carriage, holds most of the control levers. These include the levers, which engage and reverse the feed lengthwise (Z-axis) or crosswise (X-axis) and the lever which engages the threading gears. The apron is fastened to the saddle, houses the gears and mechanisms required to move the carriage and cross-slide automatically. The apron hand wheel can be turned manually to move the carriage along the Lathe bed. This hand wheel is connected to a gear that meshes in a rack fastened to the Lathe bed. The automatic feed lever engages a clutch that provides the automatic feed to the carriage

19 Cross-slide Mounted on top of saddle
Provides manual or automatic cross movement for cutting tool Compound rest (fitted on top of cross-slide) Used to support cutting tool Swiveled to any angle for taper-turning Has graduated collar that ensure accurate cutting-tool settings (.001 in.) (also cross-slide)

20 Cross-slide

21

22 Top Slide (Compound slide)
Fitted to top of Cross slide Carries tool post and cutting tool Can rotate to any angle Is used to turn tapers

23 Tailstock Upper and lower tailstock castings
Adjusted for taper or parallel turning by two screws set in base Tailstock clamp locks tailstock in any position along bed of lathe Tailstock spindle has internal taper to receive dead center Provides support for right-hand end of work

24 Tailstock Supports long workpieces when machining. Drill Chuck
60 degree rotating center point. Turn the tailstock handwheel to advance the ram.

25 Tailstock

26 Lead Screw and Feed Rod < Lead Screw < Feed Rod

27 Types of Lathes Engine Lathe Speed Lathe Bench Lathe Tool Room Lathe
Special Purpose Lathe Gap Bed Lathe

28 Size of Lathe Workpiece Length Swing

29 Size of Lathe .. Example: 300 - 1500 Lathe
Maximum Diameter of Workpiece that can be machined = SWING (= 300 mm) Maximum Length of Workpiece that can be held between Centers (=1500 mm)

30 Securely HOLD or Support while machining
Workholding Devices Equipment used to hold Workpiece – fixtures Tool - jigs Securely HOLD or Support while machining

31 Workholding Devices .. Chucks Three jaw Four Jaw

32 Chucks Used extensively for holding work for lathe machining operations Work large or unusual shape Most commonly used lathe chucks Three-jaw universal Four-jaw independent Collet chuck

33 Three-jaw Universal Chuck
Holds round and hexagonal work Grasps work quickly and accurate within few thousandths/inch Three jaws move simultaneously when adjusted by chuck wrench Caused by scroll plate into which all three jaws fit Two sets of jaw: outside chucking and inside chucking

34 Three-jaw Universal Chuck

35 Three jaw self centering chuck

36 Four-Jaw Independent Chuck
Used to hold round, square, hexagonal, and irregularly shaped workpieces Has four jaws Each can be adjusted independently by chuck wrench Jaws can be reversed to hold work by inside diameter

37 Four-Jaw Independent Chucks

38 Four-Jaw Independent Chucks
With the four jaw chuck, each jaw can be adjusted independently by rotation of the radially mounted threaded screws. Although accurate mounting of a workpiece can be time consuming, a four-jaw chuck is often necessary for non-cylindrical workpieces.

39 Workpiece (job) with a hole
Workholding Devices .. Mandrels Workpiece (job) with a hole

40 Mandrels Holds internally machined workpiece between centers so further machining operations are concentric with bore Several types, but most common Plain mandrel Expanding mandrel Gang mandrel Stub mandrel

41 Mandrels to Hold Workpieces for Turning
Figure Various types of mandrels to hold workpieces for turning. These mandrels usually are mounted between centers on a lathe. Note that in (a), both the cylindrical and the end faces of the workpiece can be machined, whereas in (b) and (c), only the cylindrical surfaces can be machined.

42 Workholding Devices .. Rests Steady Rest Follower Rest

43 Steadyrest Used to support long work held in chuck or between lathe centers Prevent springing Located on and aligned by ways of the lathe Positioned at any point along lathe bed Three jaws tipped with plastic, bronze or rollers may be adjusted to support any work diameter with steadyrest capacity

44 Steadyrest

45 Follower Rest Mounted on saddle
Travels with carriage to prevent work from springing up and away from cutting tool Cutting tool generally positioned just ahead of follower rest Provide smooth bearing surface for two jaws of follower rest

46 Follower Rest

47 Operating/Cutting Conditions
Cutting Speed v Feed f Depth of Cut d

48 Operating Conditions

49 Operating Conditions.. Cutting Speed D – Diameter (mm)
N – Revolutions per Minute (rpm) The Peripheral Speed of Workpiece past the Cutting Tool =Cutting Speed

50 Operating Conditions.. Feed
f – the distance the tool advances for every rotation of workpiece (mm/rev)

51 Operating Conditions.. Depth of Cut
perpendicular distance between machined surface and uncut surface of the Workpiece d = (D1 – D2)/2 (mm)

52 3 Operating Conditions

53 Operating Conditions.. Selection of .. Workpiece Material
Tool Material Tool signature Surface Finish Accuracy Capability of Machine Tool

54 MRR Operations on Lathe .. Material Removal Rate
Volume of material removed in one revolution MRR =  D d f mm3 Job makes N revolutions/min MRR =  D d f N (mm3/min) In terms of v MRR is given by MRR = 1000 v d f (mm3/min)

55 dimensional consistency by substituting the units
MRR Operations on Lathe .. dimensional consistency by substituting the units MRR: D d f N  (mm)(mm)(mm/rev)(rev/min) = mm3/min

56 Operations on Lathe .. Operations on Lathe Turning Chamfering Facing
knurling Grooving Parting Chamfering Taper turning Drilling Threading

57 Turning Operations on Lathe .. Cylindrical job

58 Turning .. Operations on Lathe .. Cylindrical job

59 Cutting Tool: Turning Tool
Operations on Lathe .. Turning .. Excess Material is removed to reduce Diameter Cutting Tool: Turning Tool a depth of cut of 1 mm will reduce diameter by 2 mm

60 Flat Surface/Reduce length
Facing Operations on Lathe .. Flat Surface/Reduce length

61 Facing .. Operations on Lathe .. machine end of job  Flat surface
or to Reduce Length of Job Turning Tool Feed: in direction perpendicular to workpiece axis Length of Tool Travel = radius of workpiece Depth of Cut: in direction parallel to workpiece axis

62 Facing .. Operations on Lathe ..

63 Operations on Lathe .. Eccentric Turning

64 Operations on Lathe .. Knurling Produce rough textured surface
For Decorative and/or Functional Purpose Knurling Tool A Forming Process MRR~0

65 Operations on Lathe .. Knurling

66 Knurling .. Operations on Lathe ..

67 Operations on Lathe .. Grooving Produces a Groove on workpiece Shape of tool  shape of groove Carried out using Grooving Tool  A form tool Also called Form Turning

68 Operations on Lathe .. Grooving ..

69 Operations on Lathe .. Parting Cutting workpiece into Two
Similar to grooving Parting Tool Hogging – tool rides over – at slow feed Coolant use

70 Parting .. Operations on Lathe ..

71 Chamfering Operations on Lathe ..

72 Chamfering Operations on Lathe .. Beveling sharp machined edges
Similar to form turning Chamfering tool – 45° To Avoid Sharp Edges Make Assembly Easier Improve Aesthetics

73 Operations on Lathe .. Taper Turning Taper:

74 Taper Turning.. Operations on Lathe .. Conicity Methods Form Tool
Swiveling Compound Rest Taper Turning Attachment Simultaneous Longitudinal and Cross Feeds

75 Taper Turning .. By Form Tool
Operations on Lathe ..

76 Taper Turning ,, By Compound Rest
Operations on Lathe ..

77 Drilling Operations on Lathe ..
Drill – cutting tool – held in TS – feed from TS

78 Operations on Lathe .. Process Sequence Steps: Operations Sequence
How to make job from raw material 45 long x 30 dia.? Steps: Operations Sequence Tools Process

79 Process Sequence .. Possible Sequences
Operations on Lathe .. TURNING - FACING - KNURLING TURNING - KNURLING - FACING FACING - TURNING - KNURLING FACING - KNURLING - TURNING KNURLING - FACING - TURNING KNURLING - TURNING – FACING What is an Optimal Sequence? X X X X

80 Machining Time Operations on Lathe .. Turning Time Job length Lj mm
Feed f mm/rev Job speed N rpm f N mm/min

81 Operations on Lathe .. Manufacturing Time Manufacturing Time
= Machining Time + Setup Time + Moving Time + Waiting Time

82 Example A mild steel rod having 50 mm diameter and 500 mm length is to be turned on a lathe. Determine the machining time to reduce the rod to 45 mm in one pass when cutting speed is 30 m/min and a feed of 0.7 mm/rev is used.

83 Example Given data: D = 50 mm, Lj = 500 mm v = 30 m/min, f = 0.7 mm/rev Substituting the values of v and D in calculate the required spindle speed as: N = 191 rpm

84 Example Can a machine has speed of 191 rpm? Machining time: t = 500 / (0.7191) = 3.74 minutes

85 Example Determine the angle at which the compound rest would be swiveled for cutting a taper on a workpiece having a length of 150 mm and outside diameter 80 mm. The smallest diameter on the tapered end of the rod should be 50 mm and the required length of the tapered portion is 80 mm.

86 Example Given data: D1 = 80 mm, D2 = 50 mm, Lj = 80 mm (with usual notations) tan  = (80-50) / 280 or  = The compound rest should be swiveled at 10.62o

87 Example A 150 mm long 12 mm diameter stainless steel rod is to be reduced in diameter to 10 mm by turning on a lathe in one pass. The spindle rotates at 500 rpm, and the tool is traveling at an axial speed of 200 mm/min. Calculate the cutting speed, material removal rate and the time required for machining the steel rod.

88 Example Given data: Lj = 150 mm, D1 = 12 mm, D2 = 10 mm, N = 500 rpm
Using Equation (1) v = 12500 / 1000 = m/min. depth of cut = d = (12 – 10)/2 = 1 mm

89 Example feed rate = 200 mm/min, we get the feed f in mm/rev by dividing feed rate by spindle rpm. That is f = 200/500 = 0.4 mm/rev From Equation (4), MRR = 3.142120.41500 = mm3/min from Equation (8), t = 150/(0.4500) = 0.75 min.

90 Example Calculate the time required to machine a workpiece 170 mm long, 60 mm diameter to 165 mm long 50 mm diameter. The workpiece rotates at 440 rpm, feed is 0.3 mm/rev and maximum depth of cut is 2 mm. Assume total approach and overtravel distance as 5 mm for turning operation.

91 Example Given data: Lj = 170 mm, D1 = 60 mm, D2 = 50 mm, N = 440 rpm, f = 0.3 mm/rev, d= 2 mm, How to calculate the machining time when there is more than one operation?

92 Example Time for Turning:
Total length of tool travel = job length + length of approach and overtravel L = = 175 mm Required depth to be cut = (60 – 50)/2 = 5 mm Since maximum depth of cut is 2 mm, 5 mm cannot be cut in one pass. Therefore, we calculate number of cuts or passes required. Number of cuts required = 5/2 = 2.5 or 3 (since cuts cannot be a fraction) Machining time for one cut = L / (fN) Total turning time = [L / (fN)]  Number of cuts = [175/(0.3440)]  3= min.

93 Example Time for facing:
Now, the diameter of the job is reduced to 50 mm. Recall that in case of facing operations, length of tool travel is equal to half the diameter of the job. That is, l = 25 mm. Substituting in equation 8, we get t = 25/(0.3440) = 0.18 min.

94 Example Total time: Total time for machining = Time for Turning + Time for Facing = = min. The reader should find out the total machining time if first facing is done.

95 Example From a raw material of 100 mm length and 10 mm diameter, a component having length 100 mm and diameter 8 mm is to be produced using a cutting speed of m/min and a feed rate of 0.7 mm/revolution. How many times we have to resharpen or regrind, if 1000 work-pieces are to be produced. In the taylor’s expression use constants as n = 1.2 and C = 180

96 Example Given D =10 mm , N = 1000 rpm, v = 31.41 m/minute
From Taylor’s tool life expression, we have vT n = C Substituting the values we get, (31.40)(T)1.2 = 180 or T = 4.28 min

97 Example Machining time/piece = L / (fN) = 100 / (0.71000)
= minute. Machining time for 1000 work-pieces = 1000  = min Number of resharpenings = / 4.28 = or 33 resharpenings

98 Example 6: While turning a carbon steel cylinder bar of length 3 m and diameter 0.2 m at a feed rate of 0.5 mm/revolution with an HSS tool, one of the two available cutting speeds is to be selected. These two cutting speeds are 100 m/min and 57 m/min. The tool life corresponding to the speed of 100 m/min is known to be 16 minutes with n=0.5. The cost of machining time, setup time and unproductive time together is Rs.1/sec. The cost of one tool re-sharpening is Rs.20. Which of the above two cutting speeds should be selected from the point of view of the total cost of producing this part? Prove your argument.

99 Example Given T1 = 16 minute, v1 = 100 m/minute, v2 = 57 m/minute, D = 200mm, l = 300 mm, f = 0.5 mm/rev Consider Speed of 100 m/minute N1 = (1000  v) / (  D) = (1000100) / (200) = rpm t1 = l / (fN) = 3000 / (0.5 159.2) = 37.7 minute Tool life corresponding to speed of 100 m/minute is 16 minute. Number of resharpening required = 37.7 / 16 = 2.35 or number of resharpenings = 2

100 Example Total cost = Machining cost + Cost of resharpening  Number of resharpening = 37.7601+ 202 = Rs.2302

101 Example Consider Speed of 57 m/minute
Using Taylor’s expression T2 = T1  (v1 / v2)2 with usual notations = 16  (100/57)2 = 49 minute Repeating the same procedure we get t2 = 66 minute, number of reshparpening=1 and total cost = Rs The cost is less when speed = 100 m/minute. Hence, select 100 m/minute.

102 Example Write the process sequence to be used for manufacturing the component from raw material of 175 mm length and 60 mm diameter

103 Example

104 Example To write the process sequence, first list the operations to be performed. The raw material is having size of 175 mm length and 60 mm diameter. The component shown in Figure 5.23 is having major diameter of 50 mm, step diameter of 40 mm, groove of 20 mm and threading for a length of 50 mm. The total length of job is 160 mm. Hence, the list of operations to be carried out on the job are turning, facing, thread cutting, grooving and step turning

105 Example A possible sequence for producing the component would be:
Turning (reducing completely to 50 mm) Facing (to reduce the length to 160 mm) Step turning (reducing from 50 mm to 40 mm) Thread cutting. Grooving


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