"O" FLUTES FOR MECHANICAL PLASTICS by Van Niser

"O" Flutes For Mechanical Plastics
By Van Niser.Mechanical plastics are steadily becoming the material of choice for the job shops and machine shops throughout the country. These plastics have proven to demonstrate excellent performance in gears, bearings, material-handling parts, and other machine components such as spacers and positioning mounts where reduction of vibration is essential. A few common mechanical plastics include: (ABS), Acetal, Delrin, Hydex, UHMW, nylon, polycarbonate, polyurethane, and polyethylene terephtalate (PTE). These plastics have consistently demonstrated predictable performance because of durability, machinability, and exceptional mechanical and electrical properties and are replacing metal for parts manufactured to resist wear.In terms of machining mechanicals, they can be classified as a soft plastic. Soft plastic utilizes “O” flute router type tooling that tends to curl a chip during the machining process. (Figure 1-“O” Flute Chip Action) This tooling has been designed to attack soft plastics with a high rake and low clearance geometry that actually carves the material. This tooling, when properly applied within a narrow range of chipload, typically 0.004 to 0.012, will provide an excellent finish in mechanical plastics. The consequence of improperly curled chips is visible knife marks that adversely affect the finish, which remains the most important consideration in plastic fabrication. (Figure 2-Formation of Edge Finish) “O” flute tools are manufactured from micro grain solid carbide tool material in straight and spiral configuration. The upcut, or right hand spiral is most readily utilized because of the need to evacuate chip in an upward direction in flat sheet or block applications. Upward movement of chips avoids welding, which is a common problem in the machining of plastic. The tools are available in either single or double edge cutting diameters. A single edge tool is an excellent choice for most machining applications and can accommodate those situations requiring smaller diameters. The only caution with single edge tooling is to avoid using diameters over 3/8’s because of balance issues associated with the tooling. If larger diameters are needed, the double edge alleviates the balance problem while providing a much improved bottom finish for slotting application, which are prevalent in the machining of mechanical plastics. The double edge tools additionally provide longer cutting edges for deeper cuts of two to four times the cutting edge diameter at aggressive feedrates. (Figure 3- Single Edge Spiral “O” Flute Upcut 63-750 series) and (Figure 4-Double Edge Spiral “O” Flute Upcut 52-700 series) In shops with high feed and speed CNC routers the use of router bits is common practice. The benefits of the tooling are understood, but this is not always the case in shops with CNC mills. In these environments, the tool of choice has traditionally been the endmill. These tools are intended for metal removal and do not possess the proper geometry to effectively machine mechanical plastics. Endmills have minimal rake and low clearance and were designed as robust cutting tools for heavy loads. Also, minimal flute area on these multi-edged tools interfere with the process of clearing chips, and this along with inappropriate geometry, can easily aggravate melting and rewelding problems common in mechanical plastic applications. Besides the endmill dilemma, machining methodology in many shops remains constant because of past practices associated with milling metal. The feedrates and spindle speeds tend to be slow relative to the capability of today’s CNC machining centers and climb cutting with multiple passes are commonly utilized to enhance finish. These practices adversely affect productivity, profitability, and are the antithesis of the meaning of high speed machining. In shops with high feed and speed CNC routers the use of router bits is common practice. The benefits of the tooling are understood, but this is not always the case in shops with CNC mills. In these environments, the tool of choice has traditionally been the endmill. These tools are intended for metal removal and do not possess the proper geometry to effectively machine mechanical plastics. Endmills have minimal rake and low clearance and were designed as robust cutting tools for heavy loads. Also, minimal flute area on these multi-edged tools interfere with the process of clearing chips, and this along with inappropriate geometry, can easily aggravate melting and rewelding problems common in mechanical plastic applications. Besides the endmill dilemma, machining methodology in many shops remains constant because of past practices associated with milling metal. The feedrates and spindle speeds tend to be slow relative to the capability of today’s CNC machining centers and climb cutting with multiple passes are commonly utilized to enhance finish. These practices adversely affect productivity, profitability, and are the antithesis of the meaning of high speed machining. The first step towards actual high speed machining is selecting an “O” flute router bit to machine mechanical plastics. The tool selection process is simplified by contacting a legitimate manufacturer of “O” flute router tooling with technical support capabilities. Once the proper tool is chosen, the user will be able to increase spindle speed and feedrate and boost productivity by 40 to 50 percent. In order to accommodate this process the direction of cut in almost all cases will be conventional in nature. Conventional cutting will provide a better finish by eliminating burrs associated with climb cutting and inefficient finish passes are avoided in the process. Also, the geometry associated with the “O” flute router tooling allows the user to cut without the use of coolant. This becomes particularly important in industries associated with medical devices where contamination of the mechanical plastic can become an issue. The increased feedrates associated with the heavier chiploads increases productivity and dissipates heat thus eliminating the need for coolant.The use of “O” flute router tooling represents a whole new concept in high speed machining of mechanical plastics. By selecting a tool properly designed for cutting soft plastics, and a few basic changes in machining methods, the task of producing parts from mechanical plastics can be greatly reduced, and the potential of the CNC milling machine can be fully realized.

Tooling tips

1. Double edge or Multi-Edge tools provide a better finish.


2. Use shortest cutting edge length available to make necessary depth of cut.


3. Use up/down compression spiral bits to improve top and bottom finishes on veneered or laminated materials.


4. The feed direction for a router bit should be conventional for most applications.


5. Collet and bit to be cleaned after every tooling change for longer tool life.


6. Collets should be changed on a regular basis. (400-500 run time hours).


7. Part to be fed smoothly to allow router tool to cut freely.


8. For better rigidity use straight through tool with cutting edge diameter and shank diameter the same.


9. When inserting router bit in collet do not allow flute fadeout portion of tool to extend inside of collet.


10. After you are finished cutting your material run a "cool tool" test by checking the temperature of the tool. If a proper feed and speed is utilized the tool should be at or near room temperature.


11. For longer tool life, best rigidity and best finish use solid carbide router bits.


12. The normal depth of cut should not exceed 4 times cutting edge diameter.


13. Hot corrosion is frequently the leading cause of tool wear.


14. Less heat slows down hot corrosion which reduces tool wear.


15. To increase the chip load- increase the feed rate, decrease the RPM and use less flutes.


16. To avoid friction which can cause excessive heat to the tool always avoid dead stops when routing material.


17. As chips are ejected they carry the retained heat with them.


18. Larger chips carry more heat from the cut and do not allow it to be transferred to the cutter.


19. To decrease the chipload- decrease the feed rate, increase the RPM and use more flutes.


20. Always remember your cut should produce chips not dust.


21. Straight 'O' flute cutters are ideal for thin soft plastics.


22. Single flute router bits are stronger and can feed faster than two flute.


23. Use spiral 'O' flute for excellent chip evacuation.


24. Super 'O' flute cutters (65-00 Series) is a multi-purpose tool designed for plastics, aluminum and solid-surface material. This bit is an ideal for the novice CNC operator to work on different applications.


25. When holding bit by the shank facing up, the spiral going towards the right side (counter-clockwise) indicates an upcut tool.


26. When holding bit by the shank facing up, the spiral going towards the left side (clockwise) indicates a downcut tool.


27. Natural chip formation in soft plastics is a curl.


28. Natural chip formation in Hard plastic is a block or loose curl.


29. It is important to understand when hardened collets are not replaced, over tightening will eventually damage the internal spindle taper resulting in costly repairs.


30. Timely collet replacement is important but cleaning the collet, along with the collet nut, toolholder taper and inside spindle taper each time the tools are changed is equally important.


31. Do not use petroleum based lubricant for cleaning tools or collets for it will only act as a magnet for all the dirt and dust by the residue it leaves behind.


32. To prevent a dead stop in your material while doing corners, the most effective method is to do a looped corner where the tool travels beyond the corner and loops back and intersects the original path. This provides a cooling effect on the tool as it momentarily leaves the workpiece and assures a square corner.


33. When routing use the largest Diameter tool possible 3/8"-1/2" is the best bet.


34. Use 'V' flute cutters for Hard plastics and foam.


35. Chipload is an important factor in tool life because it dictates how much heat will be carried away from the cutting edge. Better heat dissipation directly relates to increased tool life.

Router bit basics

When CNC shoppers look into purchasing a new CNC router, they look into every aspect and detail of the machine they are putting there hard earned money into. And rightfully so.
Yet one of the most overlooked aspects when purchasing a machine of this magnitude is the tooling. The popular phrase "A man is only as good as his tools" is very appropriate when dealing with CNC routers. You can own a Rolls Royce of a router and have a low quality bit in it's spindle and you might as well use a hand held router to achieve the same cut.

The router bit material, finish, geometry and cutting characteristics along with durability and long life are essential when choosing the right tool.

Some CNC owners choose the cheapest tools they can get their hands on
and without realizing they are making the poorest cost effective choice as far as productivity is concerned. Another phrase comes to mind "A penny wise and a pound foolish".

OK, enough with the popular phrases I promise.

The only time to choose the low cost bit if you must is at the start up phase of learning to operate the router. You may run in to some learning curves which may cause you to break one or two bits in the very beginning.

I personally believe in high quality as much as possible in all things. Having quality assurance and design experience in my background I can attest to this.

When choosing a router bit I highly recommend the following basics one should apply when purchasing router bits. Note that these are common characteristics and do not apply to the material being machined.

• Use solid carbide or carbide tipped tools.



• Always choose the tool with the shortest possible cutting edge length to cover the thickness of the part with a slight overlap.



• Since the diameter of the tool increases rigidity, it is best to choose the largest diameter possible and again the cutting edge length should be as short as possible and not more than three times the diameter in a perfect world.



• Keep the cutting edge length and shank diameter the same whenever possible



• Select tools on productivity rather than cost. Choose the tool for the speed of cut and finish desired, i.e., single flute for speed and larger chip loads. Double or multi flute for better finish.

These are just the basics as far as choosing a proper router bit. There are many more factors to consider like material being routed, feeds and speeds, part fixturing, chip loads etc. Although there are many different applications involved when cutting on a CNC, don''t feel overwhelmed. Whith the proper advice and direction you will eventually find your sweet spot when cutting on your CNC router and you will reap in the benefits of good high quality production.