Injection Molding Guide

Design for injection molding

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Injection Molding Guide

Design for injection molding

There are several factors that may affect the quality of the final product and the repeatability of the process. To yield the full benefits of the process, the designer must follow certain design guidelines.

In this section, we outline common defects of injection molding and basic and advanced guidelines to follow when designing parts, including recommendations for keeping the costs to a minimum.

Design for injection molding

Common injection molding defects

Most defects in injection molding are related to either the flow of the melted material or its non-uniform cooling rate during solidification.

Here is a list of defects to keep in mind while designing a part for injection molding. In the next section, we'll see how you can avoid each of them by following good design practices.

Design for injection molding defect warping

Warping

When certain sections cool (and as a result shrink) faster than others, then the part can permanently bend due to internal stresses.

Parts with non-constant wall thickness are most prone to warping.

Design for injection molding Sink marks

Sink marks

When the interior of a part solidifies before its surface, a small recess in an otherwise flat surface may appear, called a sink mark.

Parts with thick walls or poorly designed ribs are most prone to sinking.

Design for injection molding Drag marks

Drag marks

As the plastic shrinks, it applies pressure on the mold. During ejection, the walls of the part will slide and scrape against the mold, which can result to drag marks.

Parts with vertical walls (and no draft angle) are most prone to drag marks.

Design for injection molding Knit lines

Knit lines

When 2 flows meet, small hair-like discolorations may develop. These knit lines affect the parts aesthetics, but also they generally decrease the strength of the part.

Parts with abrupt geometry changes or holes are more prone to knit lines.

Design for injection molding Short shots

Short shots

Trapped air in the mold can inhibit the flow of the material during injection, resulting in an incomplete part. Good design can improve the flowability of the melted plastic.

Parts with very thin walls or poorly designed ribs are more prone to short shots.

Design rules for injection molding

One of the biggest benefits of injection molding is how easily complex geometries can be formed, allowing a single part to serve multiple functions.

Once the mold is manufactured, these complex parts can be reproduced at a very low cost. But changes to the mold design at later stages of development can be very expensive, so achieving the best results on the first time is essential. Follow the guidelines below to avoid the most common defects in injection molding.

Design for injection molding rules wall thickness

Use a constant wall thickness

Use a uniform wall thickness throughout the part (if possible) and avoid thick sections. This is essential as non-uniform walls can lead to warping or the part as the melted material cools down.

If sections of different thickness are required, make the transition as smooth as possible using a chamfer or fillet. This way the material will flow more evenly inside the cavity, ensuring that the whole mold will be fully filled.

Make the transition as smooth as possible at section of non-uniform wall thickness

Make the transition as smooth as possible at section of non-uniform wall thickness

A wall thickness between 1.2 mm and 3 mm is a safe value for most materials. The next table summarises specific recommended wall thicknesses for some of the most common injection molding materials:

Material Recommended wall thickness [mm] Recommended wall thickness [inches]
Polypropylene (PP) 0.8 - 3.8 mm 0.03'' - 0.15''
ABS 1.2 - 3.5 mm 0.045'' - 0.14''
Polyethylene (PE) 0.8 - 3.0 mm 0.03'' - 0.12''
Polystyrene (PS) 1.0 - 4.0 mm 0.04'' - 0.155''
Polyurethane (PUR) 2.0 - 20.0 mm 0.08'' - 0.785''
Nylon (PA 6) 0.8 - 3.0 mm 0.03'' - 0.12''
Polycarbonate (PC) 1.0 - 4.0 mm 0.04'' - 0.16''
PC/ABS 1.2 - 3.5 mm 0.045'' - 0.14''
POM (Delrin) 0.8 - 3.0 mm 0.03'' - 0.12''
PEEK 1.0 - 3.0 mm 0.04'' - 0.12''
Silicone 1.0 - 10.0 mm 0.04'' - 0.40''

For best results:

  Use a uniform wall thickness within the recommended values

  When different thickness are required, smoothen the transition using a chamfer or fillet with length that is 3x the difference in thickness

Hollow out thick sections

Thick sections can lead to various defects, including warping and sinking. Limiting the maximum thickness of any section of your design to the recommended values by making them hollow is essential.

To improve the strength of hollow section, use ribs to design structures of equal strength and stiffness but reduced wall thickness. A well-designed part with hollow sections is shown below:

Hollow thick sections and add ribs to improve stiffness

Hollow thick sections and add ribs to improve stiffness

Ribs can also be used to improve the stiffness of horizontal sections without increasing their thickness. Remember though that the wall thickness limitations still apply. Exceeding the recommended rib thickness (see below) can result in sink marks.

The wall thickness limitations still apply for ribs

For best results:

  Hollow out thick sections and use ribs to improve the strength and stiffness of the part

  Design ribs with max. thickness equal to 0.5x the wall thickness

  Design ribs with max. height equal to 3x the wall thickness

Design for injection molding Add smooth transitions

Add smooth transitions

Recommended: 3 × wall thickness difference

Sometimes sections with different wall thicknesses cannot be avoided. In these cases, use a chamfer or fillet to make the transition as smooth as possible.

Similarly, the base of vertical features (like ribs, bosses, snap-fits) must also always be rounded.

Design for injection molding Round all edges

Round all edges

The uniform wall thickness limitation also applies to edges and corners: the transition must be as smooth as possible to ensure good material flow.

For interior edges, use a radius of at least 0.5 x the wall thickness. For exterior edges, add a radius equal to the interior radius plus the wall thickness. This way you ensure that the thickness of the walls is constant everywhere (even at the corners).

Adding to this, sharp corners result in stress concentrations which can result in weaker parts.

Add wide radii to all edges to maintain uniform wall thickness and avoid defects

Add wide radii to all edges to maintain uniform wall thickness and avoid defects

For best results:

  Add a fillet equal to 0.5x the wall thickness to internal corners

  Add a fillet equal to 1.5x the wall thickness to external corners

Design for injection molding Add draft angles

Add draft angles

To make the ejection of the part from the mold easier, a draft angle must be added to all vertical walls. Walls without a draft angle will have drag marks on their surface, due to the high friction with the mold during ejection.

A minimum draft angle of 2° is recommended. Larger draft angles (up to 5o °) should be used on taller features.

A good rule of thumb is to increase the draft angle by one degree for every 25 mm. For example, add a draft angle of 3o degrees to a feature that is 75 mm tall. Larger draft angle should be used if the part has a textured surface finish. As a rule of thumb, add 1o to 2o extra degrees to the results of the above calculations.

Remember that draft angles are also necessary for ribs. Be aware though that adding an angle will reduce the thickness of the top of the rib, so make sure that your design complies with the recommended minimum wall thickness.

Add a draft angle (minimum 2o)to all vertical walls

Add a draft angle (minimum 2o)to all vertical walls

For best results:

  Add a minimum draft angle of 2o degrees to all vertical walls

  For features taller than 50 mm, increase the draft angle by one degree every 25 mm

  For parts with textured surface finish, increase the the draft angle by 1-2o extra degrees

Dealing with undercuts

The simplest mold (the straight-pull mold) consist of 2 halves. Features with undercuts (such as the teeth of a thread or the hook of a snap-fit joint) may not be manufacturable with a straight-pull mold though. This is either because the mold cannot be CNC machined or because the material is in the way of ejecting the part.

Undercuts in injection molding are part features that cannot be manufactured with a simple two-part mold, because material is in the way while the mold opens or during ejection.

The teeth of a thread or the hook of a snap-fit joint are examples of undercuts.

Here some ideas to help you deal with undercuts:

Design for injection molding Avoid undercuts using shutoffs

Avoid undercuts using shutoffs

Avoiding undercuts altogether might be the best option. Undercuts always add cost, complexity, and maintenance requirements to the mold. A clever redesign can often eliminate undercuts.

Shut-offs are a useful trick to deal with undercuts on internal regions of the part (for snap-fits) or on the sides of the part (for holes or handles).

Below are some examples of how injection molded parts can be redesigned to avoid undercuts: essentially, material is removed in the area under the undercut, eliminating the issue altogether.

Examples of design alteration that can help you eliminate undercuts
Examples of design alteration that can help you eliminate undercuts

Examples of design alteration that can help you eliminate undercuts
Examples of design alteration that can help you eliminate undercuts

Design for injection molding Move the parting line

Move the parting line

The simplest way to deal with an undercut is to move the parting line of the mold to intersect with it.

This solution is suitable for many designs with undercuts on an external surface. Don't forget to adjust the draft angles accordingly.

Design for injection molding Use a stripping undercut (bumpoffs)

Use a stripping undercut (bumpoffs)

Stripping undercuts (also known as bumpoffs) can be used when the feature is flexible enough to deform over the mold during ejection. Stripping undercuts are used to manufacture the threads in bottlecaps.

Undercuts can only be used under the following conditions:

- The stripping undercut must be located away from stiffening features, such as corners and ribs.

- The undercut must have a lead angle of 30o to 45o degrees.

- The injection molded part must have space and must be flexible enough to expand and deform.

It is recommended to avoid stripping undercuts in parts made from fiber reinforced plastics. Typically, flexible plastics such as PP, HDPE or Nylon (PA) can tolerate undercuts of up to 5% of their diameter.

Example part with stripping undercuts. The part is deformed as it is pushed out of the mold.
Example part with stripping undercuts. The part is deformed as it is pushed out of the mold.

Design for injection molding Sliding side-actions and cores

Sliding side-actions and cores

Sliding side-actions and cores are used when it is not possible to redesign the injection molded part to avoid undercuts.

Side-action cores are inserts that slide in as the mold closes and slide out before it opens. Keep in mind that these mechanisms add cost and complexity to the mold.

Follow these guidelines when designing a side actions:

- There needs to be space for the core to move in and out. This means that the feature must be on the other side of the part.

- The side-actions must move perpendicularly. Moving at an angle other than 90° is more complicated, increasing cost and lead times.

- Don't forget to add draft angles to your design as usual, taking in consideration the movement of the side action core.

Common design features

Learn how to design the most common features encountered in injection molded parts with these practical guidelines. Use them to improve the functionality of your designs, while still complying with the basic design rules.

Threaded fasteners (bosses and inserts)

There are 3 ways to add fasteners to an injection molded part: by designing a thread directly on the part, by adding a boss where the screw can be attached, or by including a threaded insert.

Modelling a thread directly on the part is possible, but not recommended, as the teeth of the thread are essentially undercuts, increasing drastically the complexity and cost of the mold (we will more about undercuts in a later section). An example of an injection molded part with a thread are bottle caps.

Design for injection molding Bosses

Bosses

Bosses are very common in Injection Molded parts and are used as points for attachment or assembly. They consist of cylindrical projections with holes designed to receive screws, threaded inserts, or other types of fastening and assembly hardware. A good way to think of a boss is as a rib that closes on itself in a circle.

Bosses are used as points of attachment or fastening (in conjuction with self-tapping screws or threaded inserts).

Recommended design of a boss
Recommended design of a boss

When bosses are used as points of fastening, the outer diameter of the boss should be 2x the nominal diameter of the screw or insert and its inner diameter equal to the diameter of the core of the screw. The hole of the boss should extend to the base-wall level, even if the full depth is not needed for assembly, to maintain a uniform wall thickness throughout the feature. Add a chamfer for easy insertion of the screw or insert.

For best results:

  Avoid designing bosses that merge into main walls

  Support bosses with ribs or connect them to a main wall

  For bosses with inserts, use an outer diameter equal to 2× the insert's nominal size

Design for injection molding Threads

Threads

Metal threaded inserts can be added to plastic Injection Molded parts to provide a durable threaded hole for fasteners such as machine screws. The advantage of using inserts is that they allow many cycles of assembly and disassembly.

Inserts are installed in Injection Molded parts through thermal, ultrasonic or in-mold insertion. To design a boss that will receive a threaded insert, use similar guidelines as above, using the diameter of the insert as the guiding dimension.

A threaded insert placed in a boss
A threaded insert placed in a boss

For best results:

  Avoid adding threads directly on your injection molded part

  Design bosses with an outer diameter equal 2x the nominal diameter of the screw or insert

  Add a 0.8 mm relief at the edges of the thread

  Use a thread with a pitch greater than 0.8 mm (32 threads per inch)

  Use a a trapezoidal or buttress thread

Best way to deal with the created undercuts:

  Use a thread with a pitch greater than 0.8 mm (32 threads per inch)

  For external threads, place them along the parting line

Design for injection molding Ribs

Ribs

When even the maximum recommended wall thickness is not enough to meet the functional requirements of a part, ribs can be used to improve its stiffness.

When designing ribs:

● Use a thickness equal to 0.5 × main wall thickness
● Define a height smaller than 3 × rib thickness
● Use a base fillet with radius greater then ¼ × rib thickness
● Add a draft angle of at least 0.25° - 0.5°
● Add a min. distance between ribs and walls of 4 × rib thickness

Design for injection molding Snap-fit joints

Snap-fit joints

Snap-fit joints are a very simple, economical and rapid way of joining two parts without fasteners or tools. A wide range of design possibilities exists for snap-fit joints.

As a rule of thumb, the deflection of a snap-fit joint mainly depends on its length and the permissible force that can be applied on it on its width (since its thickness is more or less defined by the wall thickness of the part). Also, snap-fit joints are another example of undercuts.

Example of an assembly with snap-fit joints
Example of an assembly with snap-fit joints

In the example above, the most common snap-fit joint design (known as the cantilever snap-fit joint) is shown. As with ribs, add a draft angle to your snap-fit joints and use a minimum thickness of 0.5x the wall thickness.

Specific guidelines on designing snap-fit joints is a big subject that goes beyond the scope of this article. For more detailed information, please refer to this article from MIT.

For best results:

  Add a draft angle to the vertical walls of your snap-fit joints

  Design snap-fits with thickness greater than 0.5x the wall thickness

  Adjust their width and length to control their deflection and permissible force

Design for injection molding Living hinges

Living hinges

Living hinges are thin sections of plastic that connect 2 segments of a part and allow it to flex and bend. Typically these hinges are incorporated in mass-produced containers, such as plastic bottles. A well-designed living hinge can last for up to a million cycles without failure.

The material used to injection mold a living hinge must be flexible. Polypropylene (PP) and Polyethylene (PE) are good choices for consumer application and Nylon (PA) for engineering uses.

A well-designed hinge is shown below. The recommended minimum thickness of the hinge ranges between 0.20 and 0.35 mm, with higher thicknesses resulting in more durable, but stiffer, parts.

Example of an living hinge (left) and recommended design dimensions for PP or PE (right)
Example of an living hinge (left) and recommended design dimensions for PP or PE (right)

Before going to full-scale production, prototype your living hinges using CNC machining or 3D printing to determine the geometry and stiffness that best fits your application. Add generous fillets and design shoulders with a uniform wall thickness as the main body of the part to improve the material flow in the mold and minimize the stresses. Divide hinges longer than 150 mm in two (or more) to improve lifetime.

For detailed guidelines, please refer to this MIT guide.

For best results:

  Design hinges with a thickness between 0.20 and 0.35 mm

  Select a flexible material (PP, PE or PA) for parts with living hinges

  Use shoulders with a thickness equal the thickness of the main wall

  Add fillets as large as possible

Design for injection molding Crush ribs

Crush ribs

Crush Ribs are small protruding features that deform to create friction when different components are pushed together, securing their possition.

Crush ribs can be an economical alternative for manufacturing high tolerance holes for tight fits. They are commonly used to house bearings or shafts and other press fit applications.

An example of a part with crush ribs is shown below. Using three crush ribs is recommended to ensure good alignment. The recommended height/radius for each rib is 2 mm. Add a minimum interference of 0.25 mm between the crush rib and the fitted part. Because of the small surface contact with the mold, crush ribs can be designed without a draft angle.

Example of an crush rib (left) and recommended design dimensions (right)
Example of an crush rib (left) and recommended design dimensions (right)

For best results:

  Add a minimum interference of 0.25 mm between crush rib and the component

  Do not add a draft angle on the vertical walls of a crush rib

Design for injection molding Lettering and symbols

Lettering and symbols

Text is a very common feature that can be useful for logos, labels, warnings, diagrams and instructions, saving the expense of stick-on or painted labels.

When adding text, choose embossed text over engraved text, as it's easier to CNC machine on the mold and thus more economical.

Also raising the text 0.5 mm above the part surface will ensure that the letters are easy to read. We recommend selecting a bold, rounded font style with uniform line thickness, with a size of 20 points or larger. Some font examples include: Century Gothic Bold, Arial and Verdana.

For best results:

  Use embossed text (0.5 mm height) instead of engraved texted

  Use a font with uniform thickness and a minimum font size of 20 points

  Align the text perpendicular to the parting line

  Use a height (or depth) greater than 0.5 mm

Design for injection molding Tolerances

Tolerances

Injection molding typically produces parts with tolerances of ± 0.500 mm (0.020’’).

Tighter tolerances are feasible in certain circumstances (down to ± 0.125 mm - and even ± 0.025 mm), but they increase the cost drastically.

For small production runs (< 10,000 units), consider using a secondary operation (such as drilling) to improve accuracy. This ensures the correct interference of the part with other components or inserts (for example, when using press fits).