1 / 51

Design for Stamping

Design for Stamping. Terry Sizemore University of Detroit-Mercy MPD Cohort 5. References. Eary and Reed: Techniques of Pressworking Sheet Metal, 2 nd ed. Prentice Hall Boothroyd, Dewhurst, Knight: Product Design for Manufacture and Assembly, 2 nd ed. Marcel Decker

Jims
Download Presentation

Design for Stamping

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. Design for Stamping Terry Sizemore University of Detroit-Mercy MPD Cohort 5

  2. References • Eary and Reed: Techniques of Pressworking Sheet Metal, 2nd ed. Prentice Hall • Boothroyd, Dewhurst, Knight: Product Design for Manufacture and Assembly, 2nd ed. Marcel Decker • Brallia: Design for Manufacturability Handbook, 2nd ed., McGraw Hill • Sizemore: EMU MFG 316 Lecture Notes • Ulrich and Eppenger

  3. Design for Stamping (DFS) • Assumptions • DFS will be “Design for Stamping” in this lecture • DFS applies to sheet materials from .035 to .1875 • Successful use of DFS is measured by: • Improvement in quality by decreasing Quality Loss (Taguchi’s quality loss function) • $$$’s of Die Cost Avoidance • Number of processes eliminated • Number reduced parts due to adding “Free” features • Number of re-orientations eliminated

  4. Product Development ProcessUlrich and Eppenger, 1995 Mission Statement Design for Stamping Concept Development System Design Detail Design Product Launch Testing/ Refinement Production Ramp up

  5. Agenda • Cutting • Theory of Cutting Sheet Metal • Forces for Cutting • Die Cutting Operations • Properties of Metals (stress strain curve, spring back, etc) • Forming • Bending • Embossing and Miscellaneous Forming • Drawing • Tooling • Design Practices

  6. Agenda • Cutting • Theory of Cutting Sheet Metal • Forces for Cutting • Die Cutting Operations • Properties of Metals (stress strain curve, spring back, etc) • Forming • Bending • Embossing and Miscellaneous Forming • Drawing • Tooling • Design Practices

  7. Theory of Cutting • Assumptions • Theory of Cutting also applies to the trimming of forgings, extrusions and castings and the cutting of bar stock • Sheet metal is anything <.125, Plate is anything >.125 • These rules do not apply to very brittle materials such as magnesium

  8. Analysis of Cutting • Forces applied by the punch and die are shearing forces, which apply a shearing stress to the material until fracture • Material deformation occurs in the plane of shear • As the tool wears and the clearance between the punch and die grow the material will begin to experience more tensile deformation and less shear deformation prior to fracture (insert figures from pg 3)

  9. Characteristics of a Die Cut Edge • Roll Over – Flow of material around the punch and die • The larger the clearance the greater the roll over • Burnish – The rubbed or “cut” portion of the edge • The sharper the punch the wider the burnish • Fracture – The angled surface where the material separates from the parent material • Burr – The very sharp projection caused by a dull cutting on the punch or die. General Rules: The more dull the tool the greater the burr. The softer the material the greater the burr. *These characteristics are evident on both the hole and slug

  10. Penetration Roll Over + Burnish = Penetration

  11. Percent Penetrations E.V. crane, Plastic Working in Presses, John Wiley and Sons, Inc., New York, 1948, p. 36

  12. Die and Punch Clearance Proper Clearance • Too Big – Blank ends up with roll-over and/or a crown effect. • Too Small – Results in large stripping force and secondary shear. Secondary shear is when the fracture propagating from the punch misses the fracture propagating from the die. • When proper clearance exists the fractures meet, which yields a preferable break edge.

  13. Die and Punch Clearance • Force Curves – Using strain gages or other transducers to create force vs. displacement curves is a common tool for analyzing various clearance conditions. Poor clearance conditions result in less than ideal force curves (may put in curves???)

  14. Other Characteristics • Dish Distortion • Spacing Distortion – When holes are punched next to each other in sequence distortion in the circularity and position of the first hole will occur. If possible punch closely proximate holes simultaneously. See attached table for recommended design practices. (insert figure and chart from page 20)

  15. Forces for Cutting For Cutting: • In general ferrous stamping materials, shear strength is 70-80% ultimate tensile strength • Force=Shear Strength*Perimeter of Cut*Thickness • When calculating tonnage required it is recommended that ultimate tensile strength be used instead of shear strength to compensate for die wear. Tonnage=(UTS*Perimeter*Thickness)/2000

  16. Forces for Cutting • Take caution in what number is used for shear strength or UTS. Consideration must be made for prior operations that may affect the material properties. • Work Hardening • Annealing or Tempering • Other processes that affect the mechanical properties of the material

  17. Work and Energy • In terms of metal cutting: Work=average force*distance • Force: Since the force/displacement curve for cutting sheet metal is nearly rectangular use the maximum force prior to fracture as the average force • Distance: The distance used in this calculation is percent penetration (see earlier slide) multiplied by material thickness. • This calculation assumes no secondary shear, which will require additional energy during cutting.

  18. Example 10 inch diameter aluminum blank made from .032 inch 3003 aluminum (3003 UTS is 11000 psi) Force=(11000)(3.14)(10)(.032) =11053 lbs Tonnage=11053/2000=5.5 tons Work=(5.500)(.600)(.032)=.1056 inch tons* (Need to insert penetration chart page 10) *Most press flywheels are rated in inch ton capacity

  19. Cutting Operations • Blanking – Material removed is the work-piece • Piercing – Material removed is scrap • Lancing – No metal removed, bending and cutting • Cut-off/Parting- Separating parts or reducing scrap strip size • Notching – Removing material from the outer edges of the strip • Shaving – Removing the break edge • Trimming – Removing “Flash” from drawn parts

  20. Blanking

  21. Piercing

  22. Lancing

  23. Cut-Off/Parting

  24. Notching

  25. Shaving

  26. Trimming

  27. Agenda • Cutting • Theory of Cutting Sheet Metal • Forces for Cutting • Die Cutting Operations • Properties of Metals (stress strain curve, spring back, etc) • Forming • Bending • Embossing and Miscellaneous Forming • Drawing • Tooling • Design Practices

  28. Stress/Strain Curves Insert Curve with details

  29. Geology of Stress Strain Curve • Elastic Region • Yield Point • Necking Region • Ultimate Point • Elongation • Spring Back

  30. Spring Back

  31. Agenda • Cutting • Theory of Cutting Sheet Metal • Forces for Cutting • Die Cutting Operations • Properties of Metals (stress strain curve, spring back, etc) • Forming • Bending • Embossing and Miscellaneous Forming • Drawing • Tooling • Design Practices

  32. Forming Limit Diagram

  33. Bending

  34. Embossing

  35. Drawing

  36. Hydro-forming

  37. Agenda • Cutting • Theory of Cutting Sheet Metal • Forces for Cutting • Die Cutting Operations • Properties of Metals (stress strain curve, spring back, etc) • Forming • Bending • Embossing and Miscellaneous Forming • Drawing • Tooling • Design Practices

  38. Most automotive stampings created by transfer press Automation “transfers” part from die to die First picture shows stampings transferred from the side Second picture shows stampings transferred from the front and back Transfer Dies

  39. Create only bottom half of the die (cheaper and faster) Sheet metal placed over die Rubber-like material placed over sheet metal High pressure water forms part Hydro-forming - Bladder press

  40. Dies fed directly from steel coil No need for blanking operation Scrap get cut away as part gets formed Restricted to simple parts Progressive Dies

  41. Flexible Forming Dies

  42. Rubber Pad Dies

  43. Tooling Materials

  44. Agenda • Cutting • Theory of Cutting Sheet Metal • Forces for Cutting • Die Cutting Operations • Properties of Metals (stress strain curve, spring back, etc) • Forming • Bending • Embossing and Miscellaneous Forming • Drawing • Tooling • Design Practices

  45. Stamping Applications • Can accommodate many functional features and attachment features • Natural uniform wall thickness • Can incorporate • Springs • Snap fit • Tabs • Spot welding • Material Thickness from .001 in to .790 in

  46. Production • 35 to 500 parts per minute • 250000 per year minimum to justify using progressive die • Progressive Die should eliminate at least two secondary operations before consideration • Short run press tooling – Short run is when the cost of the tool exceeds the cost of the parts • Punch presses should be used for low volume parts when possible

  47. Materials • Any material that can be produced in sheet can be press-worked • Deep drawn parts require “Draw Quality” steels • Non-ferrous metals may require modified processing or additional processing steps

  48. Design Recommendations • Shaping and nesting on strip • Stamp multiple parts on same strip to increase strip utilization • Design part/strip so part can be “cut-off”, not “blanked” • Holes • Diameter not less then T, spacing should be 2T to 3T • 1.5 to 2T between a hole and edge • 1.5T + bending radius spacing between surface and hole • Use pilot holes

  49. Design Recommendations • Avoid sharp corners • Improves tool wear • Increases bur size • Lowers stress • Minimum radius of .5T or .03125 • Be aware of grain direction • Long sections should greater than 1.5T wide to avoid distortion and a weak problematic tool design

  50. Design Recommendations • Use stiffening ribs or darts when more strength is needed • Use extruded holes when threaded fasteners must be used (1.5 T is the max thread contact you can achieve) • Set-outs – used for location, rivets, etc. • Height to be .5T • Be aware of the burr

More Related