1. Tolerancing
Chapter 11

2. Need for Tolerance . Exact size is difficult to manufacture.
Exact size is not required.
The replacement of parts should be easy.

3. Tolerance Dimensioning
Tolerance is the total amount that a specific dimension is permitted to vary
Maximum & minimum allowable dimensions are called Limit Dimensions.
Tolerance is the difference between the maximum and the minimum limits for the dimension.
For Example a dimension given as ± .002 means that the manufactured part may be 1.627” or 1.623”, or anywhere between these limit dimensions.

4. Shaft:. A member which fit in another member Hole:
Shaft: A member which fit in another member Hole: A member in which external member fit.
The Tolerance is 0.001” for the Hole as well as for the Shaft

5. Size Designations
Nominal Size: Used for general identification calling name.
Basic Size: This is the size on which tolerances are applied.
Actual size: measured size of the finished parts.

6. Fit between mating parts
Fit is the general term used to signify the range of tightness or looseness that may result from the application of a specific combination of allowances and tolerances in mating parts.
Types of fits
Clearance Fit
Interface fit
Transition fit

7. Fits between Mating Parts continued…
Clearance Fit A clearance fit occurs when an internal
part fits into an external part with space (or clearance) between the parts.
Interference Fit An interference fit occurs when the internal part is larger than the external part, so the parts must be forced together.

8. Transition fit:
Max Clearance = – = Allowance = – =

9. Maximum Clearance = Max Hole – Min Shaft Allowance (Minimum Clearance) = Min Hole – Max Shaft

10. Maximum Interference = Max Shaft– Min Hole
Maximum Interference = Max Shaft– Min Hole Minimum Interference = Min Shaft – Max Hole

11. Hole System Toleranced dimensions are commonly
determined using the hole system.
(Lockhart, Shawna D.; Johnson, Cindy M.,
Engineering Design Communication: Conveying Design Through Graphics, 1st, © Printed and electronically reproduced by permission of Pearson Education, Inc., Upper Saddle River, New Jersey.)

12. Shaft System
In some industries, such as textile machinery manufacturing, which use a great deal of cold-finished shafting, the shaft system is used.
(Lockhart, Shawna D.: Johnson, Cindy M., Engineering Design Communication: Conveying Design Through Graphics, 1st, © Printed and electronically reproduced by permission of Pearson Education, Inc., Upper Saddle River, New Jersey.)

13. Basic Hole System
Minimum hole size is taken as the basic size, an allowance is assigned, and tolerances are applied on both sides of and away from this allowance.
The minimum size of the hole 0.500” is taken as the basic size.
An allowance of 0.002” is decided on and subtracted from the basic hole size, making the maximum shaft as 0.498”.
Tolerances of 0.002” and 0.003” respectively are applied to the hole and shaft to obtain the maximum hole of 0.502” and the minimum shaft of 0.495”.
Minimum clearance: 0.500”-0.498” = 0.002”
Maximum clearance: 0.502” – 0.495” = 0.007”

14. Basic Shaft System
Maximum shaft size is taken as the basic size, an allowance is assigned, and tolerances are applied on both sides of and away from this allowance.
The maximum size of the shaft 0.500” is taken as the basic size.
An allowance of 0.002” is decided on and added to the basic shaft size, making the minimum hole as 0.502”.
Tolerances of 0.003” and 0.001” respectively are applied to the hole and shaft to obtain the maximum hole of 0.505” and the minimum shaft of 0.499”.
Minimum clearance: 0.502”-0.500” = 0.002”
Maximum clearance: 0.505” – 0.499” = 0.006”

15. GENERAL TOLERANCE NOTES
“ALL TOLERANCES ±1 mm
UNLESS OTHERWISE NOTED.
ANGLES 1 DEGREE.”
General notes are usually located in the lower right corner of the drawing sheet near the title block. Often, general tolerance notes are included in the title block itself.

16. LIMIT TOLERANCES
Limit tolerances state the upper and lower limits for the dimension range in
place of the dimension values.
Method of Stating Limits
Note: The upper value is always placed above
the lower value.

17. PLUS-OR-MINUS TOLERANCES
• Unilateral when the tolerance applies in only one direction
so that one value is zero; or,
• Bilateral when either the same or different values are
added and subtracted.

18. Symmetry in bilateral dimension

19. Angular tolerances
Angular tolerances are usually bilateral and given in terms of degrees, minutes, and seconds, unless geometric dimensioning and tolerancing is used.
Plus/Minus–Toleranced
Decimal Dimensions

20. TOLERANCE STACKING
A Chained dimension uses the end of one dimension as the beginning of the next.
Tolerance stacking refers to the way the tolerance for one dimension is added to
the next dimension in the chain and so on from one feature to the next, resulting in a
large variation in the location of the last feature in the chain.
Baseline dimensioning locates a series of features from a common base feature.
Tolerances do not stack up because dimensions are not based on other toleranced
dimensions.

21. TOLERANCES AND MACHINING PROCESSES
Tolerances Related to Machining Processes

22. Metric system of tolerances and fit Specified by International Organization for Standardization (ISO). Basic Size: The size where limits are assigns. Deviation: Different between the basic and hole or shaft size. Upper Deviation: Difference between the basic and maximum size. Lower Deviation: Difference between the basic and minimum size. Fundamental deviation: The deviation which is closest to the basic size. For Shaft: upper deviation is the fundamental deviation For Hole: Lower deviation is the fundamental deviation

23. METRIC SYSTEM OF TOLERANCES AND FITS
Terms Related to Metric Limits and Fits.
(Reprinted from ASME B , by permission of The American Society of Mechanical Engineers. All rights reserved.)

24. Basic Hole System For Hole Lower Deviation = Min Hole – basic size
Upper Deviation = Max Hole – basic size
Fundamental Deviation is Lower deviation
Fundamental deviation represents in capital letters, A, B, C ,…..H, G, ……AA,……
Each letter has its own number can be seen in hand books. H means zero.
If Fundamental deviation is H, it means minimum hole size is the basic size and the system is called basic hole system.

25. Basic Shaft System For shaft, Lower Deviation = basic size – min shaft
Upper Deviation = basic size – max shaft
Fundamental Deviation is upper deviation
Fundamental deviation represents in small letters, a, b, c ,…..h, g, ……aa,……
Each letter has its own number can be seen in hand books. h means zero.
If Fundamental deviation is h, it means maximum shaft size is the basic size and the system is called basic shaft system.

26. IT Grade for Tolerances
Tolerances: Difference between maximum and minimum size.
International Tolerance Grade (IT) Set of tolerances that varies according to the basic size and provide uniform level of accuracy.
Total 18 IT grade, IT01, IT0, IT1,…IT16.

31. Example of IT Grade (p-a33)
40h6 shaft, basic size 40, Tolerance 0.016
Max size = 40, Min size =
30H10 Hole, basic size 30, Tolerance 0.084
Min size = 30, Max size =

32. Basic Size = 50, Basic Hole System. Max. Min. Tol Hole. 50. 039. 50
Basic Size = 50, Basic Hole System Max Min Tol Hole Shaft Max. Clearance = 0.089, Allowance = 0.025, Clearance fit.

33. Another example, 45N7/h6 Basic size = 45 and Basic shaft system.
Max Min Tol
Hole
Shaft
Max.Clearance = and allowance =
Transition fit
(Take Higher values and subtract the difference)