1 / 34

GTD

GTD. Geometric Tolerances and Dimensions. Why Geometric Tolerances and Dimensioning. To ensure interchangeability of mating parts during assembly To eliminate controversy and guesswork when drawing is interpreted

chuong
Download Presentation

GTD

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. GTD Geometric Tolerances and Dimensions

  2. Why Geometric Tolerances and Dimensioning • To ensure interchangeability of mating parts during assembly • To eliminate controversy and guesswork when drawing is interpreted • To ensure the drawing reflects the form and function requirements of the manufactured parts

  3. Principles of datum specification Three perfect plans used to locate an imperfect part. • Three point contact is used on the primary plane. b. Two point contact is used on the secondary plane. c. One point contact is used on the tertiary plane

  4. datum specification

  5. One-Plane Datum Reference Frame

  6. Two-Plane Datum Reference Frame

  7. Three-Plane Datum Reference Frame

  8. Symbols Advantages: 1. The symbol has uniform meaning. 2. Symbols are compact, quickly drawn, and can be placed on the drawing where the control applies. 3. Symbols are the international language and surmount individual language barriers. 4. Geometric tolerance symbols follow the established precedent of other well known symbol systems, e.g., electrical and electronic, welding, surface texture.

  9. Using Symbols

  10. Using Notes

  11. Symbols/Notes

  12. Material Condition

  13. HOLE PIN

  14. MMC • The actual local size of the hole at. 245 and the pin at Ø .240 of the figure are the Maximum material condition Ø

  15. LMC • The actual local size of the hole at Ø .255 and the pin atØ .230 of the figure are the least material condition

  16. TERMINOLOGY • VIRTUAL CONDITION - A constant boundary generated by the collective effects of a size feature’s specified MMC or LMC and the geometric tolerance for that material condition.

  17. VIRTUAL CONDITION • Virtual condition, based on MMC or L M C is a feature‘s extreme boundary; it represents the “worse case” • For MMC, “worse case” concerns fits and/or clearances with mating parts For LMC, “worst case” is concerned with strength, alignment, wall thickness, etc. with reference to mating parts

  18. VIRTUAL CONDITION (MMC- PIN) • Virtual Condition for a Pin (Based on Maximum Material Condition) = Maximum Material Condition + the Stated Position or Orientation Tolerance • VC = MMC + Tolerance

  19. VIRTUAL CONDITION (MMC- PIN)

  20. VIRTUAL CONDITION (MMC- Hole) • Virtual Condition for a Hole (Based on Maximum Material Condition) = Maximum Material Condition - the Stated Position or Orientation Tolerance • VC = MMC - Tolerance

  21. VIRTUAL CONDITION (MMC- Hole)

  22. VIRTUAL CONDITION (LMC- PIN) • Virtual Condition for a Pin (Based on Least Material Condition) = Least Material Condition - the Stated Position or Orientation Tolerance • VC = LMC - Tolerance

  23. VIRTUAL CONDITION (LMC- PIN)

  24. VIRTUAL CONDITION (LMC- Hole) • Virtual Condition for a Hole (Based on Least Material Condition) = Least Material Condition + the Stated Position or Orientation Tolerance • VC = LMC + Tolerance

  25. VIRTUAL CONDITION (LMC- Hole)

More Related