Category Archives: Mold Design

Mold tool design

Cooling the Mold

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This explains the WHY, WHAT, HOW and WHERE of mold temperature control.

Why do we need to control the mold temperature?

The mold temperature has significant impact on molding cycle, dimensional accuracy of molded part, and warping of molded part.

If the mold temperature is too cool, the runner and gate will solidify before the resin could completely fill up the cavity. However, if the mold temperature is too hot, the resin will take more time to solidify affecting the molding cycle time. If some portions of the molded part solidify a lot faster than the other portions, chances are warp or deformed molded part –the dimensional accuracy cannot be satisfied.

What are the methods of controlling the mold temperature?

There are 3 methods to control the temperature of the mold. It depends on the temperature range that the mold will be set for production.

1.    Water:    40~90?

2.    Oil:    80~120?

3.    Heater cartridge: 120? and over.

How and where should we apply the mold temperature control?

The purpose is to control the temperature of the cavity and core so keep the cooling line (water hole) close and evenly placed around the molded part. The image below shows the ideal placement of water hole. But this is only a general rule -mold structure, manufacturability, and ease of maintenance are to be considered.

Mold Design Using Solidworks

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Solidworks is a nice tool to help you design molds. It is easy to learn with its intuitive user interface and easy to use for experienced users.

Of course you must have the necessary knowledge of fundamentals of mold design and mold making in order to use this tool to its full potential.

This video is very helpful for aspiring mold designers using Solidworks.

Free 3D CAD: CoCreate Modeling PE 3.0

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I received this email from PTC 2 days ago…

The latest version of CoCreate Modeling PE, the world’s first free explicit 3D CAD software, is now available.

Download it today, and get all the flexibility of our standard CoCreate Modeling 3D CAD system free for assemblies up to 60 parts.

New in CoCreate Modeling PE 3.0:

  • Real-time explicit modeling
  • Context-sensitive mini toolbars for fast access to commands
  • Dimension-driven design changes
  • Support for Microsoft Windows 7
  • And much more …

Are you interested in free 2D CAD?

Free 2D CAD for DWG files: an alternative to Autocad

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Yesterday, while surfing the internet looking for new tools for mold design, I discovered DraftSight, a 2D CAD tool from the Dessault Systemes. DraftSight is available for free download. Is it going to be valuable tool for mold design? One way to find out…

I downloaded the installation file (about 42Mb) to give it a try. The installation was quick and easy. I have to send my email to activate the software.

The interface has a clean layout and it has a command line, much like Autocad. Unfortunately for me, I use a very different 2D CAD software at work.

Below are my observation about DraftSight.

  • FREE download for everyone. Professionals or students.
  • Performance is slower than my 2D CAD.
  • Very Autocad like. Therefore, difficult to use… at least for me.
  • LINUX version will be available later this year. This is good news.

I do not know for how long DraftSight is going to be free, so download it now.

Are you more interested in free 3D CAD tool?

How much does a mold cost?

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The cost of injection mold is dependent on the shape or geometry of the molded part, mold steel cost including standard components, and engineering cost (labor cost). It is important to note that labor and material cost greatly varies on geographical location. Labor cost from US, EU, or Japan can be 10 to 20 times more than that of China, India or Philippines but the quality is almost same. Yes, almost same quality. Well, slightly lower but sometimes better.

Mold Cost U.S. versus China

Putting out the geographic factor, the mold can be classified by its precision type and usage factor. Precision types are explained below:

  1. High Grade (HG) molded parts are parts with all features having important functionality. The product drawings are completely detailed showing all features being dimensioned with a very tight dimensional tolerances. The general part tolerance is (+/-)0.15mm while specified tolerances are as tight as (+/-)0.02mm. Every part dimensions will be computed individually and must be remodeled into CAD to ensure accuracy and fit. The precision level of every mold part is very high because it involve a lot of fits and shut-offs. A typical example of these parts are wiring harness connectors.
  2. Medium Grade (MG) molded parts are parts with fewer important functional parts than HG. The general dimensional tolerance are usually (+/-)0.25mm, specified and non-specified. Functional shapes such as clip locks does not go tighter than (+/-)0.05mm. Critical parts does not exceed 50% of the total specified dimensions. A typical example of these are auto fuse box and insulators.
  3. Shape Parts (SP) are part where only a few shapes are functional. 3D CAD file from customer can be used directly with minimal modification for mold making. Examples are caps and covers.

COST ANALYSIS OF PLASTIC INJECTION MOLDS

Classification by usage are as follows:

CLASS-101 CLASS-102 CLASS-103 CLASS-104 CLASS-105
Cycles 1M and up 500K to 1M 100K to 500K 500 to 100K Lower than 500
Mold base min hardness 28 HRC 28 HRC 8 HRC mild steel or AL mild steel or AL
CAV and CORE min hardness 58 HRC 48 HRC 38 HRC 30 HRC mild steel or AL

Molds are made differently so mold shops should have their own quotation standards. Very busy shops tend to quote higher than shops with very few jobs. The simpler mold, the better and cheaper.

Mold type and classification chart was referenced from EMAMOLD.


Cavity and Core

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This article describes the cavity and core, its processing method, and its arrangement into the mold. More reference like this are described in Mold-Making Handbook

Cavity and core

cav-core

Core and cavity can be classified into 2 methods, integrated and nested method. You can choose which method will define your cavity and core.

Integrated: When the molded part is formed directly by the die.

Nested: When the molded part is formed by the die components.

Nested Cavity and Core

Benefits:

  • There is no restriction to the geometry of the molded part. Processing efficiency can be done when components are separated.
  • Mold materials can selected for better wear resistance and temperature control.
  • Damaged components can be replaces easily and cost effectively.

Mold-Making Handbook
Engineering References)

Mold Structure

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This will describe the structure of 2-plate, 3-plate, and runnerless molds.

The basic structure of a molding die is determined by the geometry of the molded part, its production volume, molding material/resin, and consideration of other technical and production constraints such as positioning of gate.

2-Plate Mold Configuration

The mold is divided by parting-line (PL) into two parts, the movable and fixed side.

Features:

  • The structure is simpler compared to 3-plate and runnerless mold.
  • Tooling cost is normally lower.
  • Side gate, submarine gate, and direct gate system are typical. More about gate system.

Drawbacks:

  • Side gate and direct gate are not suited to save labor cost through automation.

3-Plate Mold Configuration

The mold is divided by 2 PL into three separate parts. The 1st PL is on the runner separating the runner stripper plate and the fixed side plate. The pin-gate is automatically cut off from the product on 1st PL. The 2nd PL is on the product separating the movable and fixed sides.

Features:

  • Suitable for full automation.

Drawbacks:

  • Mold structure is more complex than 2-plate structure.
  • Tooling cost is higher.

Runnerless Mold Configuration

2-plate and 3-plate molds produce product plus runner. Runnerless molds can be achieved by introducing hot runners.

Features:

  • Runners will not be discarded at all so cost of material is less.
  • Sprue and runner is always in the heater maintaining its fluid state for good filling of molten plastics to cavities.
  • There are several advantages for high volume production.
  • Suitable for full automation.

Drawbacks:

  • Complex structure.
  • Much higher price.
  • It takes time to replace the material.

How to design mold cavity and core in 2D Autocad

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The old fashioned way but still being used by some mold manufacturers. Designing a mold cavity and core in 2D. Some mold designers may use different procedure. You can use Autocad, Solidworks, ProE, or just plain tracing paper and pencil in this mold design tutorial.

Product to mold drawing

7 Steps:

  1. Calculate 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 calculated mold dimension. Include 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. The mirrored drawing 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. Locate it away from small core pins to avoid damaging those pins during resin injection process. 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 or trace your cavity and core drawings using your mold drawing as reference.

A Typical Injection Mold Design Guide

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This checklist can be used as a general reference guide for injection mold design engineers. It is divided into 3 parts of a mold design process.

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.