1 / 52

GEOMETRIC DIMENSIONING & TOLERANCING ANSI Y14.5M 1994

GEOMETRIC DIMENSIONING & TOLERANCING ANSI Y14.5M 1994. Based on fit, form and function of a part and to control the relationship between part features. Three Categories of Dimensioning. Dimensioning can be divided into three categories: general dimensioning, geometric dimensioning, and

Audrey
Download Presentation

GEOMETRIC DIMENSIONING & TOLERANCING ANSI Y14.5M 1994

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. GEOMETRIC DIMENSIONING & TOLERANCINGANSI Y14.5M 1994 Based on fit, form and function of a part and to control the relationship between part features

  2. Three Categories of Dimensioning Dimensioning can be divided into three categories: • general dimensioning, • geometric dimensioning, and • surface texture. The following provides information necessary to begin to understand geometric dimensioning and tolerancing (GD&T)

  3. Geometric Dimensioning & Tolerancing (GD&T) • GD&T is a means of dimensioning & tolerancing a drawing which considers the function of the part and how this part functions with related parts. • This allows a drawing to contain a more defined feature more accurately, without increasing tolerances.

  4. GD&T cont’d • GD&T has increased in practice in last 15 years because of ISO 9000. • ISO 9000 requires not only that something be required, but how it is to be controlled. For example, how round does a round feature have to be? • GD&T is a system that uses standard symbols to indicate tolerances that are based on the feature’s geometry. • Sometimes called feature based dimensioning & tolerancing or true position dimensioning & tolerancing • GD&T practices are specified in ANSI Y14.5M-1994.

  5. For Example • Given Table Height • However, all surfaces have a degree of waviness, or smoothness. For example, the surface of a 2 x 4 is much wavier (rough) than the surface of a piece of glass. • As the table height is dimensioned, the following table would pass inspection. • If top must be flatter, you could tighten the tolerance to ± 1/32. • However, now the height is restricted to 26.97 to 27.03 meaning good tables would be rejected.

  6. Example cont’d. • You can have both, by using GD&T. • The table height may any height between 26 and 28 inches. • The table top must be flat within 1/16. (±1/32)

  7. WHY IS GD&T IMPORTANT • Saves money • For example, if large number of parts are being made – GD&T can reduce or eliminate inspection of some features. • Provides “bonus” tolerance • Ensures design, dimension, and tolerance requirements as they relate to the actual function • Ensures interchangeability of mating parts at the assembly • Provides uniformity • It is a universal understanding of the symbols instead of words

  8. WHEN TO USE GD&T • When part features are critical to a function or interchangeability • When functional gaging is desirable • When datum references are desirable to insure consistency between design • When standard interpretation or tolerance is not already implied • When it allows a better choice of machining processes to be made for production of a part

  9. TERMINOLOGY REVIEW • Maximum Material Condition (MMC): The condition where a size feature contains the maximum amount of material within the stated limits of size. I.e., largest shaft and smallest hole. • Minimum Material Condition (LMC): The condition where a size feature contains the least amount of material within the stated limits of size. I.e., smallest shaft and largest hole. • Tolerance: Difference between MMC and LMC limits of a single dimension. • Allowance: Difference between the MMC of two mating parts. (Minimum clearance and maximum interference) • Basic Dimension: Nominal dimension from which tolerances are derived.

  10. LIMITS OF SIZE A variation in form is allowed between the least material condition (LMC) and the maximum material condition (MMC). EnvelopPrinciple defines the size and form relationships between mating parts.

  11. ENVELOPE PRINCIPLE LMC CLEARANCE MMC ALLOWANCE LIMITS OF SIZE

  12. LIMITS OF SIZE The actual size of the feature at any cross section must be within the size boundary. ØMMC ØLMC

  13. LIMITS OF SIZE No portion of the feature may be outside a perfect form barrier at maximum material condition (MMC).

  14. Other Factors I.e., Parallel Line Tolerance Zones

  15. TYPE OF TYPE OF FEATURE TOLERANCE FLATNESS INDIVIDUAL (No Datum Reference) STRAIGHTNESS FORM CIRCULARITY CYLINDRICITY INDIVIDUAL or RELATED FEATURES LINE PROFILE PROFILE SURFACE PROFILE PERPENDICULARITY ORIENTATION ANGULARITY PARALLELISM RELATED FEATURES (Datum Reference Required) CIRCULAR RUNOUT RUNOUT TOTAL RUNOUT CONCENTRICITY POSITION LOCATION SYMMETRY GEOMETRIC CHARACTERISTIC CONTROLS 14 characteristics that may be controlled CHARACTERISTIC SYMBOL

  16. Characteristics & Symbolscont’d. • Maximum Material Condition MMC • Regardless of Feature Size RFS • Least Material Condition LMC • Projected Tolerance Zone • Diametrical (Cylindrical) Tolerance Zone or Feature • Basic, or Exact, Dimension • Datum Feature Symbol • Feature Control Frame

  17. FEATURE CONTROL FRAME GEOMETRIC SYMBOL TOLERANCE INFORMATION DATUM REFERENCES COMPARTMENT VARIABLES THE RELATIVE TO OF THE FEATURE MUST BE WITHIN CONNECTING WORDS Feature Control Frame

  18. Feature Control Frame • Uses feature control frames to indicate tolerance • Reads as: The position of the feature must bewithin a .003 diametrical tolerance zoneat maximum material condition relative to datums A, B, and C.

  19. ^ PURPOSE OF A DATUM • TO REPEATABLY LOCATE A PART FOR INSPECTION OR MANUFACTURE • TO COMMUNICATE FUNCTIONAL DESIGN INFORMATION

  20. ^ Introduction • Datum • theoretically perfect point, line or plane. • Datum References • letters shown in feature control frames. • Datum Features • physical features on a part from which measurements are made.

  21. Line up with arrow only when the feature is a feature of size and is being defined as the datum A OR A A ANSI 1982 ASME 1994 Placement of Datums • Datums are generally placed on a feature, a centerline, or a plane depending on how dimensions need to be referenced.

  22. Example Datums • Datums must be perpendicular to each other • Primary • Secondary • Tertiary Datum

  23. ^ • C • B • A Precedence

  24. ^ Precedence • Secondary • Tertiary • Primary

  25. ^ Precedence • Secondary: 2 Contact “Points” • Tertiary: 1 Contact “Point” • Primary: 3 Contact “Points”

  26. The of the feature must be within a tolerance zone. The of the feature must be within a tolerance zone at relative to Datum . The of the feature must be within a tolerance zone relative to Datum . The of the feature must be within a zone at relative to Datum . The of the feature must be within a tolerance zone relative to datums . Reading Feature Control Frames

  27. Placement of Feature Control Frames • May be attached at side, end, or corner of the symbol box to an extension line. • Applied to surface. • Applied to axis

  28. Ø .500±.005 Placement of Feature Control Frames Cont’d. • May be below or closely adjacent to the dimension or note pertaining to that feature.

  29. Basic Dimension • A theoretically exact size, profile, orientation, or location of a feature or datum target, therefore, a basic dimension is untoleranced. • Most often used with position, angularity, and profile) • Basic dimensions have a rectangle surrounding it.

  30. Basic Dimension cont’d.

  31. Orientation Tolerances • Perpendicularity • Angularity • Parallelism • Controls the orientation of individual features • Datums are required • Shape of tolerance zone: 2 parallel lines, 2 parallel planes, and cylindrical

  32. PERPENDICULARITY: • is the condition of a surface, center plane, or axis at a right angle (90°) to a datum plane or axis. Ex: The perpendicularity of this surface must be within a .005 tolerance zone relative to datum A. The tolerance zone is the space between the 2 parallel lines. They are perpendicular to the datum plane and spaced .005 apart.

  33. PERPENDICULARITYCont’d. • Location of hole (axis) This means ‘the hole (axis) must be perpendicular within a diametrical tolerance zone of .010 relative to datum A’

  34. ANGULARITY: The surface is at a 45º angle with a .005 tolerance zone relative to datum A. • is the condition of a surface, axis, or median plane which is at a specific angle (other than 90°) from a datum plane or axis. • Can be applied to an axis at MMC. • Typically must have a basic dimension.

  35. PARALLELISM: • The condition of a surface or center plane equidistant at all points from a datum plane, or an axis. • The distance between the parallel lines, or surfaces, is specified by the geometric tolerance.

  36. Material Conditions • Maximum Material Condition (MMC) • Least Material Condition (LMC) • Regardless of Feature Size(RFS)

  37. Maximum Material Condition • MMC • This is when part will weigh the most. • MMC for a shaft is the largest allowable size. • MMC of Ø0.240±.005? • MMC for a hole is the smallest allowable size. • MMC of Ø0.250±.005? • Permits greater possible tolerance as the part feature sizes vary from their calculated MMC • Ensures interchangeability • Used • With interrelated features with respect to location • Size, such as, hole, slot, pin, etc.

  38. Least Material Condition • LMC • This is when part will weigh the least. • LMC for a shaft is the smallest allowable diameter. • LMC of Ø0.240±.005? • LMC for a hole is the largest allowable diameter. • LMC of Ø0.250±.005?

  39. Regardless of Feature Size • RFS • Requires that the condition of the material NOT be considered. • Tolerance is applied no matter what the size of the feature is. • Valid only when applied to features of size, such as holes, slots, pins, etc., with an axis or center plane.

  40. Limits of Size Rule • A feature of size must be within the stated upper and lower size limits. At any cross-section the part must not exceed the MMC or LMC. • The feature may not exceed a perfect form boundary at MMC. If the part were produced at MMC, it cannot have any deviation in form. • The part may vary between the LMC and the MMC.

  41. Location Tolerances • Position • Concentricity • Symmetry

  42. Position Tolerance • A position tolerance is the total permissible variation in the location of a feature about its exact true position. • For cylindrical features, the position tolerance zone is typically a cylinder within which the axis of the feature must lie. • For other features, the center plane of the feature must fit in the space between two parallel planes. • The exact position of the feature is located with basic dimensions. • The position tolerance is typically associated with the size tolerance of the feature. • Datums are required.

  43. Coordinate System Position • Consider the following hole dimensioned with coordinate dimensions: • The tolerance zone for the location (axis) of the hole is as follows: • Several Problems: • Two points, equidistant from true position may not be accepted. • Total tolerance diagonally is .014, which may be more than was intended. Center can be anywhere along the diagonal line. .750 2.000

  44. Position Tolerancing • Consider the same hole, but add GD&T: • Now, overall tolerance zone is: • The actual center of the hole (axis) must lie in the round tolerance zone. The same tolerance is applied, regardless of the direction. MMC =

  45. Bonus Tolerancing • Geometric tolerancing has on one major advantage built in; the bonus tolerance application. Bonus tolerances can be obtained on geometric controls where the maximum material condition (MMC) or least material condition (LMC) is used. Bonus tolerances are calculated as follows: Original Tolerance at MMC – Actual Size = Bonus Tolerance Total Possible Tolerance = Original Tolerance at MMC + Bonus Tolerance

  46. Bonus Tolerance • Here is the beauty of the system! The specified tolerance was: This means that the tolerance is .010 if the hole size is the MMC size, or .497. If the hole is bigger, we get a bonus tolerance equal to the difference between the MMC size and the actual size.

  47. Bonus Tolerance Example This means that the tolerance is .010 if the hole size is the MMC size, or .497. If the hole is bigger, we get a bonus tolerance equal to the difference between the MMC size and the actual size. This system makes sense… the larger the hole is, the more it can deviate from true position and still fit in the mating condition!

  48. .503 - .497 = BONUS .006 BONUS + TOL. ZONE = .016

  49. Restrictions on Bonus Tolerancing • You can never go beyond print size dimensions to get more bonus tolerance. • Bonus tolerances can only be used in cases where if all possible bonus tolerance were used, it would not affect the function of the part assembly. • Bonus tolerancing applies only on geometric controls where MMC or LMC applies.

  50. Geometric Dimensioning and Tolerancing Manufacturing Engineering Technology Virtual Condition (Actual) • The virtual condition (VC) is the collective effects of the size and any geometric tolerances of form, orientation, or position. The following are calculations for the virtual conditions of a shaft and a hole: • Shaft: VC = maximum diameter + geometric tolerance • Hole: VC = minimum diameter + geometric tolerance

More Related