Tag Archives: Acetal

Machining Acetal Shapes

Highly precise acetal parts in a variety of sizes and complexities can be manufactured economically through machining. In the world of Engineering Plastics, Acetal (POM) stock shapes are considered to be some of the easiest to machine. On a scale of 1-10 with 1 being the easiest, many manufacturers place acetal at a 1, compared to a PBI which is often seen as a 10. In fact, machine shops that traditionally make metal parts find they can machine acetal using the same primary tools used for most of the metals they work with. As with any material, there are some good guidelines that can help ensure your success.

Best General Practices for Machining Parts from Acetal (POM) Engineering plastic and Potential Pitfalls of Machining Thermoplastic Shapes

We love engineering plastics! So we are always touting the many benefits of replacing plastics with metals. But this does not mean they are perfect in every way in every situation. There are some differences between plastics and metals that can trip you up when machining. But once you know the potential problems of machining acetal stock shapes machining them can become as easy as the metals machine shops are used to working with now.

Watch out for the heat! As a general rule keep in mind that, due to heat, thermoplastics expansion can be up to 10X greater than metals. Thermoplastics also hold heat longer than metals. Acetal is a thermoplastic material and has a lower thermal conductive aspect than most of the metals it is used to replace. Heat may not be an issue for metals but in the case of an engineering plastic shape from acetal heat build up from machining needs to be monitored and taken into account. Thermoplastics are more elastic than metals. So in general, heat buildup during the machining process can potentially lead to thermal expansion which can distort acetal parts.

If this leaves you concerned about machining plastics, not to worry! Plastics like acetal have numerous benefits that often outweigh the challenges of heat buildup and once you understand how to work with acetal you can easily machine consistently accurate, detailed high quality parts that your customers will be happy with. Be mindful of heat buildup, but also know that acetal does not typically require a coolant (except when drilling or threading). Sawing and machining can usually be set up to minimize heat buildup. (See the table below for Quadrant Engineering Plastics general recommendations for tools and speeds.)

  1. If cooling is used on acetal, compressed air is the standard method. The great thing is this has two benefits. The air cools the part and it keeps chips blown out of the way and keeps the heat built up in the chips off of the part or tools where it can add to any heat buildup. Other options include spray mists and non-aromatic, water soluble coolants.
  2. Sharper tools = Less friction = Less heat. To help reduce heat buildup use extremely sharp cutting tools.
  3. Chipping. Acetal creates chips when being machined so plan for removal of chips as you machine. Removing chips is very important in deep hole drilling. As the chips add to the heat, hole walls can heat to the melting point and clog the drill.
  4. Pieces may be flexible. Make sure the acetal is supported in a way that the material is not distorted, bent, twisted or allowed to deflect away from the tool.
  5. Make sure machining equipment is running as smoothly as possible, reduce any vibration to help aid in accuracy and part quality.
  6. Acetal shapes can be clamped but be aware of how tight.
  7. Choose the right blade for the job. Start by asking yourself what the end product is going to be.
    1. Band saws are good choice for a support groove and for cutting acetal rod and tube. Heat gets dissipated over the long blade.
    2. Circular saws are a good choice for cutting acetal sheet or blocks that have straight edges. Watch the feed speed (most acetal manufacturers have a recommendation).
  8. Choose the right tool for the job too
    1. Opt for positive tool geometries with ground peripheries
    2. For best tool life use carbide tools with ground top surfaces
  9. Is post machining annealing needed? See our previous blog post on this topic.
  10. Choose a machining cycle that will allow for evacuation of the chips from holes and cutting surfaces. For example, when drilling holes choose a cycle that allows drill to ‘peck’ or withdraw at certain points to draw chips back out of the hole.

The following tables are a good starting point for how to set up machining of acetal materials. The information comes two US manufacturers of acetal materials – Quadrant Engineering Plastics and Engineer Plastics provide guidelines for machining the acetal materials they produce. Depending on the manufacturer acetal materials may go through a stress relieving (annealing process) as part of their manufacturing. This helps to ensure the highest possible consistent quality of materials. Testing and consulting with your local tkEP representative on manufacturer recommendations is always a good way to help prevent machining problems. tkEP representatives not only have a broad range of industry experience, many have worked hands on in the industry, and all tkEP representatives attend manufacturer training so we stay on top of current products and how to work them.


As you can see each manufacturer has their own insights into how acetal should be sawn, milled, drilled, or turned. Their are also some pretty broad ranges when it comes to the numbers they provide. This is because these are truly general guidelines that cover the broad range of acetal shapes. Acetal shapes can be acetal homopolymers, acetal copolymer. In addition there are filled acetals and unfilled acetals. Add that to other variations including thickness and size plus environment and it is easy to see that testing for individual applications is necessary.

To read more about acetal plastic shapes check out our online catalog. We have product information as well as a full range of shapes, sizes, and grades of acetal. Read More… For more detailed information on machining from Quadrant EPP and Ensinger Engineering Plastics we’ve included links to pdf files of their machining guides. In these guides you’ll find data for acetals as well as a broad range of other machinable engineering plastics. Last but not least, don’t forget about your friendly local tkEP representative. We are always happy to assist you with finding the right engineered plastics solution for your application. Contact us today 877.246.7700. this one number will put you in contact with your local tkEP branch, or send us a note.

Quadrant Engineering Plastics Machinist Handbook

Ensinger Engineering Plastics Machinist Guide

What’s That Plastic?

Have you ever come across a plastic material, a sheet, rod, or tube, in your shop or warehouse with no label and no way to determine exactly what it is? This can be a difficult challenge due to incredible number of variations that include all the machinable engineering plastics plus all the fillers and additives used to enhance or improve aspects of an engineering plastic’s performance under specific conditions.
However, there are some things you can do to get off to a good start on narrowing down the options.
We’ve put together a handy infographic on some simple do it yourself tests and how the most popular engineering plastics will react to them.

In addition to these methods take a look at our blog post on using the Burn / Flame Test to Identify Plastic Materials


Engineering Plastics use Grows in Food Processing Equipment

iStock_000014977093LargeEngineering Plastics continue to replace metals as key components in food processing equipment. Plastics are often lighter and able to outlast traditional metal parts. A quick look through the variety of plastics available in today’s market shows an increasing number of engineering plastics that are compliant to FDA, USDA, 3A Dairy standards making them available in applications where they will come into direct contact with food. They are also being chosen for their
ability to create a quieter work environment.

With 2014 looking to be a great year for Food Processing equipment sales I wanted to share what we most find in food processing applications and why.

UHMW continues to lead the way (by pounds sold in the United States) in the transformation from metal to plastic parts.  For more information on materials sold in the U.S. see this article by the American Chemical Council. Compared to steel UHMW is just 1/7th the weight. In addition UHMW is corrosion resistant. UHMW is a great option for room temperature applications like guides, paddles, and cutting surfaces.  Recent advances include the introduction of metal detectable versions that can be recognized by your detection systems in line.

For bearing and wear applications, Nylon materials have been the workhorse for over 30 years.  Like UHMW, Nylon is also light weight, and provides lubrication – free operation making it a great material for producing bearings or bushings.  Gears and sprockets made of Nylon have been popular because they can reduce noise in work areas. They can also improve the efficiency of production lines conveying food and liquids in your plants by lasting longer than metals, which reduces downtime, and by allowing lines to run faster.

For many components, Acetal is the best choice for metal replacement, and we find its popularity is growing quickly in the food processing industry.  Acetal (Delrin Homopolymer or CoPolymer brands like Acetron GP and Celcon) are very easy to machine, and their very low moisture absorption rates make them a good choice for the often wet environment of food processing.  Acetals are harder than Nylons and maintain dimensional stability where Nylons tend to be more flexible. In many applications Acetals can handle continuous use temperatures up to 210° F and they are typically compatible with most cleaning solutions, a huge plus in the food processing industry.

A popular speciality material is Quadrant Engineering Plastics Ertalyte material.  Ertalyte has unique properties that allow it to wear like Acetal in wet environments and like Nylon in dry or unlubricated environments.  I like to think of it as giving you the best of both worlds! Ertalyte also is highly resistant to stains generated by things like tomato based sauces and green vegetables.  Ertalyte also has high dimensional stability that meets the demands of the highly precise machining tolerances required in filling pistons and fluid manifolds.

In looking to the future of food processing the demands are heavy. Companies are working hard to keep consumer prices in line while still making a profit. Food processing companies are achieving these goals by improving efficiency and creating better work environments. Plastics are an increasingly big part of the solution because their use in parts can improve line speeds, decrease maintenance downtime, and even make for a quieter work environment.

As I look at the Engineering Plastics and High Performance Materials we have here at AIN Plastics I’m pleased to see how they are being used to improve the food processing industry and I’m excited to see the new applications our customers are working on as well as the new materials our suppliers are always working on. If you have an application you’ve been scratching your head over, give us a call. We know there are lots of options and we can help you take some of the guess work out of finding out if Engineering Plastics are right for your application.

Paul Hanson

Sales and Marketing Manager
DuPont Vespel®
ThyssenKrupp Materials NA
AIN Plastics Division

email: paul.hanson@thyssenkrupp.com

For more information on Engineering Plastics visit http://www.tkmna.com/tkmna/Products/Plastics/Engineering/index.html