From Art to Part 2009From Art to Part 2009Plastics Plastics Part DesignPart Design
By: Sidney Wong & KM HoTel: 27667616, 27667620
E-mail: [email protected]@polyu.edu.hk
Intended Learning OutcomesIntended Learning Outcomes
After completing this training session, YOU are expected able to:
� Address the key design concepts for thermoplastic part design
� List out the common thermoplastic part assembly methods , select and applying them in the group methods , select and applying them in the group project
� Apply general plastic design rules/ simple calculation in designing a thermoplastic product
General Design Rules of Injection General Design Rules of Injection MouldMouldeded PartPart
�Uniform wall thickness�Part Geometries�Draft Angle
Radii / Fillet�Radii / Fillet�Structural Ribs Design�Bosses �Snap-Fit Design
Uniform Wall ThicknessUniform Wall Thickness (UWT)(UWT)
� Why Uniform Wall Thickness is important in plastic part design?
� Non-uniform and/or heavy wall thicknesses can cause serious warpage and dimensional control cause serious warpage and dimensional control problems in the injection molded products. Heavy wall sections cause not only internal shrinkage, voids, and surface sink marks, butalso non-uniform shrinkage resulting in poor dimensional control and warpage problems.
Uniform Wall ThicknessUniform Wall Thickness (UWT)(UWT)
Uniform Wall ThicknessUniform Wall Thickness (UWT)(UWT)RIBS
How to achieve UWTHow to achieve UWT
Coring ((((偷空偷空偷空偷空))))should be employed where possible to eliminate material masses in the part. When wall thickness transitions cannot be avoided, the transition should be made gradually, on the order of 3 to 1.
Part GeometriesPart GeometriesAlthough UWT is achieved, sometimes the part geometries itself will generate moulding problems
Part GeometriesPart Geometries
Task 1Task 1
�Try to modify below part geometry to improve the manufacturability
Draft AngleDraft Angle
Draft angles for internaland external walls areessential to the ejectionof the moulded partsf r o m t h e m o u l d .f r o m t h e m o u l d .External walls requiresmaller draft anglesthan the internal walls.
Draft AngleDraft Angle
Minimum Draft AngleMinimum Draft AngleExternal Wall Internal Wall
W/O Texture
W/ Texture W/O Texture
W/ Texture
Depth < 1” 0° 15′ to 0°30′
(0° 15′ to 0°30′) +
0° 30′ to 1° (0° 30′ to 1°) +30′ 30′) + +
Depth > 1” 1.0° to1.0° 30′
(1.0° to1.0° 30′) +
1.0° 30′ to 3.0°
(1.0° 30′ to 3.0°) +
Radii / FilletRadii / Fillet
Internal sharp corners and notches are the leading cause of failure in injection moulded thermoplastic parts. To avoid the problem occurred, radii / fillet is commonly employed to all “sharp” feature all “sharp” feature
Radii / FilletRadii / Fillet
A fillet radius should be between 25 to 60% the nominal wall thickness. The larger fillet radius is suggested for load carrying features
Radii / FilletRadii / Fillet
The outside corner radius should be equal to the inside radii plus the wall radii plus the wall thickness (R = r + t).
Structural RibStructural Ribss DesignDesign
�Rib is one of the common features used in plastic part design to strength the structure and to reduce the weight of the product.
Structural RibStructural Ribss DesignDesign
� However, for many resins, the use of ribs will produce sink marks on the external surface and this defect becomes very noticeable on the moulded product.
� There are several resins on the market that have good surface appearance behind the rib area, for example, PVC, ABS, PC, LCP, PBT, PETPVC, ABS, PC, LCP, PBT, PET
Structural RibStructural Ribss DesignDesign
Structural RibStructural Ribss DesignDesign•The thickness of the rib at the intersection withthe nominal wall should be 50 to 60% of thenominal wall.•Maximum rib height: h=3 x nominal wall thickness.•Typical draft for ribs is 1 to 1.5°. Minimum draftshould be 1/2° per side.•Spacing between two parallel ribs should be a•Spacing between two parallel ribs should be aminimum of 2 x wall thickness.
Task 2Task 2
�Try to integrate the concept of “Draft”, “Fillet” & Rips to enhance the design
BossesBosses
�Bosses are thermoplastic cylinders attached to a side wall or end corners. Special self-tapping screws are used to mount other components. The boss’s outside and hole’s inside diameters are outside and hole’s inside diameters are based on size, depth and type of screws, pullout torque requirements, resin modulus of elasticity, creep, and boss weld line strength.
BossesBosses
BossesBosses
BossesBosses
� Typically the boss OD = 2 ID.� The wall thickness at the base of
the boss should remain less than 60% of the nominal wall thickness.
� The boss height should be less than 3 ´ OD.than 3 ´ OD.
� Draft on the OD is 1/2° and ID is 1/4° Min.
� Keep the minimum distance of twice the nominal wall thickness between 2 bosses.
SnapSnap--Fit DesignFit Design
� Snap fits are commonly used as an assembly method for injection molded parts. Snap fits are very useful because they eliminate screws, clips, adhesives, or other joining methods. The snaps are molded into the product, so additional parts are molded into the product, so additional parts are not needed to join them together.
� There are three main types of snap fits: Annular, Cantilever, and Torsional.
http://engr.bd.psu.edu/pkoch/plasticdesign/snap_design.htm
Annular Snap FitAnnular Snap Fit
� ASJs are generally stronger, but need greater assembly force than their cantilevered counterparts.
� Annular Snap Fit are basically interference rings. � Annular Snap Fit are basically interference rings.
http://machinedesign.com/ContentItem/61167/FundamentalsofAnnularSnapFitJoints.aspx
Annular Snap Fit Annular Snap Fit –– childchild--proof bottlesproof bottles
The ridge geometry of the annular snap-fit plug determines the assembly force F needed to engage the joint. A shallow return angle of 30°A shallow return angle of 30°easily separates while a 90°angle is permanent. Designers of child-proof bottles employ a clever trick to transform a permanent snap joint into one that easily disengages.
http://machinedesign.com/ContentItem/61167/FundamentalsofAnnularSnapFitJoints.aspx
Key points of applying Annular Snap FitKey points of applying Annular Snap Fit
� Don’t use cylindrical snap-fits with very stiff materials, making the plug from a more rigid material than its mating female hub.
� Use an engagement angle of 20° to 30° and a Use an engagement angle of 20 to 30 and a release angle of 40° to 50°.
� Place the undercut near the open end of the hub.� Size the undercut so that the design stress
figure is not exceeded.
Cantilever Snap FitCantilever Snap Fit
Cantilever snap fits are the most widely used type of snap fit. There is a considerable amount of calculation and of calculation and engineering that goes into designing a good snap fit
http://engr.bd.psu.edu/pkoch/plasticdesign/snap_design.htm
Cantilever Snap FitCantilever Snap Fit
http://engr.bd.psu.edu/pkoch/plasticdesign/snap_design.htm
Key points of applying Cantilever Snap FitKey points of applying Cantilever Snap Fit
� Keep within the allowable strain figure.� If the calculated allowable deflection is too small,
try increasing the snap hook length.� Design so that the snap hook is no longer flexed
after it has clicked into the catchafter it has clicked into the catch� Snap-fits are meant to be used either once or
just a few times, so fatigue and wear can be neglected.
� Radius the root of the snap hook to reduce stress concentration.
Torsional Snap FitTorsional Snap Fit
� The torsional snap-fit relies for its spring effect on twisting rather than flexing like the other types.
� It is a good way of fastening a hinged lid on a box or container.box or container.
Key points of applying Torsional Snap FitKey points of applying Torsional Snap Fit
� Use torsional snap-fits when you want to be able to release the catch easily.
� Include a design feature to show where to press.� Design a stop feature to prevent excessive
torsion.torsion.� Do not make the catch lever length too short
otherwise the twist angle and torsion becomes too great.
� Reduce the opening force by making the length of the opening lever longer than the catch lever.
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