Assumptions:

1. You already have the plastic product drawing in paper not CAD.
2. You know the meaning of plastic shrinkage factor, draft angle, parting line, and mold cavity and core.
3. You know how to draw.

7 Steps:

1. Compute for the mold dimension using the shrinkage factor.
   • The shrinkage factor can be determined by resin material properties or by experimenting. For example the PBT has a shrinkage of 18/1000.
   • Compensate for the tolerance and other possible deformation.
   • Include the draft angle whenever possible. The draft angle should be within the dimensional tolerance.
2. Draw product drawing using the computed mold dimension. Do not forget the embossed texts if it is a part of the product drawing. It is a good idea to draw the embossed texts using lines and curves. If your CAD is capable of “reflecting a text” then you are in advantage.
3. Mirror or flip your product drawing and that will be your mold drawing. Notice that the embossed texts were also mirrored and they became engraved text.
4. Decide and draw the gate location. Remember to locate it away from small core pins. For our example, I would like to use “side-gate”.
5. Decide the parting line. Input the parting line changes if there are any. Parting line changes should be visible on the top view, draw that too.
6. Decide the ejector location. Divide the mold drawing as you wish or as your process capability would dictate. Consider dividing on gas vents.
7. You can then derive your cavity and core drawings using your mold drawing as reference.

Part 1 - Requirements to start your mold design:

1. Check the injection machine where the mold is to be mounted. This will help you decide the size and structure of the mold for ease of installation and other factors. Important notes:
   • Locating ring size (or other positioning method)
   • Nozzle size
   • Method of clamping (Auto or manual)
   • Temperature control system
2. Determine the number of cavities and volume requirements. This will help you decide the material that you are going to use and other mold components that you will choose for cost effective design.
3. Determine the gate location and size.
4. Determine the location where ejector pin marks are prohibited.

Part 2 - Mold base layout:

1. Place cavities close to the center of the mold to minimize base size and runner length.
2. Ensure that the molded part remains on the movable half (ejector half) upon opening of PL to facilitate proper ejection.
3. Waterlines should be placed as evenly as possible to the contours of the cavity.
4. Use support pillars underneath the cavity pockets.
5. Use ejector guides for molds with small ejector pins and rectangular ejector pins.
6. Provide eye-bolt hole for ease of mounting and dismounting.
7. Install mold opening prevention locks on the operator side.
8. Establish pry bar groove on the corners of the mold parting line to facilitate ease of mold opening during assembly and maintenance.

By this time you may ask for the mold layout approval from the customer.

Part 3 - Cavity/core details:

1. Check material shrinkage. Locate portions (corners) for possible significant deflection and deformation.
2. Maintain uniform wall thickness.
3. Draft angle should be within dimension tolerance.
4. Divide core blocks to simplify machining and provide gas vent path.
5. Gate, small cores, and cores with shut-off fittings are better designed as insertable components for easy modification and repair.
6. Watch out for possible deformation of core pins.
7. Position the ejector pins on the ribs and other high strength locations. Ensure ejector balance.
8. Detailing/part drawing: Include all parameters needed for processing -material, quantity, surface finish/texture, dimensions, tolerances and many more. Do not assume the machinist understands everything.

Any design change and amendments to the mold must be re-approved by the customer or mold owner.

Few extras that could make your mold one step further in terms of quality:

1. Bevel edges. Whenever possible use machine to bevel the edges.
2. Minimize scratches on the mold base. Keep the work table clean.

This checklist may be updated regularly so I suggest you “bookmark” if you find it useful.

Download “A Typical Injection Mold Design Guide” in PDF

It includes 7 tutorials: introduction, part modeling, sketching, drawing creation, patterns, assembly components, and re-using 2D files. When you finish the tutorials in one day you can have 29 more days to practice and familiarize with the software. If you are a mechanical engineer and you don’t have a job then try to study this CAD 8 hours a day. By the time the free license expires you should already completed 240 hours CAD training that you can add to your resume. Cool idea!

Fixed Clamping Plate

Locating Ring
It is used to locate the center of the injection machine so that the sprue bushing and the nozzle are aligned. Commonly fitted into the counterbore in the fixed clamping plate.

Fixed Cavity Plate
Used to hold the fixed cavity block, leader pin/bushing, and sprue bushing.

Movable Cavity Plate
Used to hold the movable cavity block, leader pin/bushing.

Movable Clamping Plate
Holds The movable side of the mold to the movale platen of the injection machine.

Spacer Block
Mounted between the movable clamping plate and the movable cavity plate to give space and allow the ejector plate to move when ejecting the
part.

Ejector Retainer Plate
Holds the ejector pins and the return pins in place.

Ejector Plate
Pushes the ejector pins and return pins at the same time. Mounted to the ejector retainer plate to form the ejector unit.

Support Pillars
Bars placed between the spacer blocks to give additional support to the movable cavity plate.

Sprue Bushing
Has a tapered hole through which the material is forced into the runner. It is butted up against the nozzle of the injection machine.

Return Pins
Same as ejector return pins. Make sure that the ejector unit is back in its original position when the mold closes.

Leader Pins and Bushings
Precisely align the two halves of the mold base (fixed and movable).

Side gate: This is the most commonly used gate type and is commonly used for mold structures with 2 or more cavities. It is placed at the side of the plastic product. The gate has to be cut manually by a cutter.

Submarine gate: The positioning of this gate is flexible thoughout the sides of the plastic product. It can be placed on the fixed or movable side of the mold but the design has to be thought about carefully so that the product will not be left inside the fixed cavity. The gate automatically cuts itself as the mold opens.

Fan gate: It is commonly used for large and flat plate products. It is placed at the side of the product - same as the side gate. The gate has to be cut manually by a cutter.

Film gate: Similar to fan gate except that it is commonly used for thin and flat plate products.

Pin gate: This is possible for molding multiple cavities or parts. The gate positioning is relatively flexible at the top side of the product. The runner layout is very flexible as well. The mold base structure is complicated because it uses a 3-plate method.

Banana gate: This is not a very common gate. It is used when the visible surface of the product requires no trace of the gate. The gate automatically cuts itself as the mold opens.

Direct gate: The sprue serves as the gate. It is placed on the top side of the product. The gate has to be cut manually by a cutter. This gate type can only produce one part per shot. The molding cost is low because the material from the runner was ellimenated. The injection pressure was reduced due to direct cavity filling. The simple mold structure makes the mold cost lower.

Injection molding is an economical and very efficient method of producing plastic parts. It can produce millions of parts with exactly the same shape, dimension, and quality. Some examples of injection molded parts are the mobile phones, mouse, keyboard, and many components found inside the automobile.

What is an injection mold?

An injection mold is a device made of metal to produce a plastic product faster, less expensive, and more consistent.

How does injection molding works?

Just heat the plastic until it melts then force it into the cool mold. Allow it to solidify. Open the mold then take off the molded part.

That’s it!

Okey.. as the molten plastic material is being injected into the mold, it enters the mold opening called the sprue. From the sprue this molten material will then be distributed to the runners then it will be fored into the gate and then into the cavity.

The cavity must be filled precisely to avoid short shots but it must not be over packed (over packing is forcing more than enough material and it can damage the mold). The molten material will stay in the cavity for 30 seconds to 1 minute or more until it cools down and solidify.

When the material solidify a plastic part is formed. The mold will open and then the plastic part is being ejected. The mold closes and its ready for another shot.

Why is an injection mold expensive?

Injection molds are made up of special, high quality materials that have a good machinability property. Some standard mold components such as springs, bolts, and limit switch are prefabricated and costs lower.

Most standard components such as ejector pins, ejector sleeves, and sprue bushings are not prefabricated which mean they will only be manufactured when you order them. They are not mass produced thus they are expensive.

The cavity and core are mold components which make the mold really expensive. It involves careful design engineering and processing. Most of the tools used in making these components are very expensive.