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ROUTING: Link to Article Archive. (Nov/Dec-18)
ROUTING: Top Ten Routing Questions (Sep/Oct-08)
ROUTING: Routing Polyethylene (Mar/Apr-08)
ROUTING: Routing & Trimming Polypropylene (Mar/Apr-08)
ROUTING: Routing Polycarbonate (Jan/Feb-08)
ROUTING: Routing See-Throughs (Nov/Dec-07)
ROUTING: Real World Routing Solutions (Sep/Oct-07)
ROUTING: Real World Routing Solutions (Jul/Aug-07)
ROUTING: Real World Routing Solutions (May/Jun-07)
ROUTING: Real World Routing Solutions (Mar/Apr-07)
ROUTING: Achieving Premium Finishes When Routing Acrylic (Jan/Feb-07)
ROUTING: Preparing for Plastic Routing Part II (Nov/Dec-06)
ROUTING: Preparing for Plastic Routing Part I (Sep/Oct-06)
ROUTING: The Router Way (Jul/Aug-06)
ROUTING: Routing With Air (May/Jun-06)
ROUTING: Routing & Trimming PET (Mar/Apr-06)
ROUTING: Router Bits for the Sign Industry (Jan/Feb-06)
ROUTING: Machining Plastics: Optimizing Cutting Tool Productivity (Nov/Dec-05)
ROUTING: Routing & Fixturing ABS (Sep/Oct-05)
ROUTING: Major Considerations in the Routing of Plastic (Jul/Aug-05)
ROUTING: The Importance Of Spoilboards (May/Jun-05)
ROUTING: Removing The Heat From Cutting Tools (Mar/Apr-05)
ROUTING: Fixturing & Routing Plastics With CNC Tooling (Jan/Feb-05)
ROUTING: Proper Colleting And Maintenance In CNC Routing Of Plastic (Nov/Dec-04)
ROUTING: Routing Composites (Jul/Aug-04)
ROUTING: Plastic Routing FAQs (May/Jun-04)
ROUTING: Plastic Routing FAQs (Mar/Apr-04)
ROUTING: Plastic Routing FAQs (Jan/Feb-04)
ROUTING: Routing Polyethylene (Sep/Oct-03)
ROUTING: Reduce Routing Cost$ (Jul/Aug-03)
ROUTING: Router Bits For CNC Mills (May/Jun-03)
ROUTING: Routing Acrylic (Mar/Apr-03)
ROUTING: Trimming Thermoformed Parts (Jan/Feb-03)
SERIES: ROUTING
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ROUTING: Routing & Fixturing ABS

The fixturing method, feed rate and chip flow control can determine
the type of tooling used when machining ABS.

ABS is one of the most popular plastics used by thermoformers and rotational molders. It is also one of the most versatile, from low-density foam to highdensity material. It has been used in consumer products for years and is becoming the material of choice in many auto and truck components.

ABS combines toughness, stability, wide temperature range and chemical resistance with relative ease of fabrication. That, combined with its low water absorption and high to low gloss range in a variety of colors, often makes it the plastic formula of choice for a wide range of applications.

Instrument panels, headliners, grilles, wheel covers, decorative trim, mirror housings, truck bed liners and bumper farings are some of the applications in which ABS has been used successfully. Small and large appliances, refrigerator door liners, business machine and electronic housings, luggage, toys, storage bins and flower pots also made from ABS are often trimmed by air or CNC routers. Pipe and fence materials made from ABS are used in several products requiring unique routing methods.

Using a Spoilboard

ABS is a reasonably-priced material and can be machined in a most cost-effective manner. While the substantive properties of this material would often dictate restrictive machining practices in other formulations, this is not the case with ABS. There are just a few — but important — considerations when routing or trimming ABS.

In many instances, CNC routers are set up with the right tools and an elaborate vacuum system. The spoilboard, however, is overlooked and becomes the problem area. The one thing that can make or break an ABS setup is the ability to hold a part on the table “rock solid.” ABS parts are normally quite flexible and will tend to vibrate if not fixtured properly. There are many elaborate pod systems employed by both point-topoint machines and routers. These systems can be very effective. There are also many machines utilizing dedicated spoilboards to hold parts. This is most often the case with ABS parts. The proper way to build a dedicated spoilboard is often misunderstood or cut short, in the interest of time. Taking the time to do it right will pay dividends in the form of productivity and piece part finish.

Many people consider a spoilboard a piece of MDF or particleboard with self-stick weather-stripping and a few holes drilled inside the perimeter. While this type of fixture may work in a few instances, it does not often satisfy the demands made in high-performance routing. If a router is going to run at production speed, the parts must not move. The preferred spoilboard technique employs grooving the interior area of the gasket perimeter to allow a vacuum to reach the outermost portion of the part. The holes are then drilled at the intersection of the vacuum grids.

The method provides a greater vacuum surface area. It is preferred to just drilling holes in the spoilboard because it provides a “bead” of vacuum to the outermost edge of the part, giving the best chance for a “rock solid” hold. (Figure 1)

Tool Selection

Once the ABS has been properly fixtured, tool selection is a straightforward process. The router bit of choice for most thermoformed sheet, 6mm or less, is the O flute tool, either single or double edge.

In many instances, the part can be machined while cooling. High-speed steel tools work very well in this instance. (Figure 2) In all instances, ABS can be trimmed and routed effectively with solid carbide O flute tools. (Figure 3) A newer product in solid carbide router bits for plastic applications is the O flute spiral tool. (Figure 4) While available for many years in straight or shear geometry, recent developments in CNC grinding technology has enabled the design and manufacture of the O flute spiral, which provides for better chip flow control in certain applications.

Reweldment

One of the few problems in machining ABS can be chip reweldment. This occurs when the chip is not removed properly or quick enough. It can also occur when the feed rate is too slow.

While these problems can be easily resolved in a CNC environment with proper fixturing and tool selection, they can be more difficult to solve in hand-held or air routing applications. Depending on the difficulty of the setup, fabricators may want to consider using carbide-tipped straight flute tools if high speed steel does not provide satisfactory tool life. (Figure 5) In these situations, carbide-tipped tools may be preferable to solid carbide because of the strength of the tool steel body. Whether the router is CNC or hand-held, ramp entry into the ABS workpiece — rather than straight plunge — will also prevent rewelding.

In any plastic routing application, fabricators should experiment with both single- and double-edge bits, as well as both spiral and straight flutes, to determine the best tool for the specific job.

For more information, click on the author biography at the top of this page.

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