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Meeting the demands of a complex application

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Composite material cutters offer a growing opportunity for specialised cutting tool manufacturers with 9.3% predicted growth for carbon fibre reinforced plastics by 2025*.


The idea of using fibres embedded in a supporting matrix has been around longer initially appreciated. From the earliest beginnings of mud bricks reinforced with straw - to the first composite bows made with wood, bone and pine resin - it was recognised that composite materials deliver superior properties than if used in isolation.  
The aerospace and defence, wind energy, automotive, civil construction and sporting goods industries have all come to adopt composites for high performance applications – and the demand continues to grow.  A report by Credence Research in 2019 estimated a CAGR of 9.3% for carbon fibre reinforced plastics during the period 2017-2025. Duncan Thompson, Product Manager at ANCA, notes the increased sales inquiries in this area, reflecting a growing demand by tool manufacturers to produce cutting tools to service this specialist market.  
Duncan comments, “commercial applications for composites continues grow, and with that, the market space for specialised cutting tools also expands. Cutting tool manufacturers need to adopt a variety of cutting tool designs and technologies, developing specialised tools for the wide and varied range of composites used today. ANCA has been working with customers to design innovative software that help address these needs, creating new tool geometries, and machines that can grind or erode market leading CFRP cutting tool solutions.”

Understanding the composite market  

Today’s composites industry uses a variety of matrix materials (thermoset epoxy, phenolic, polyimide, etc.) and fibres (carbon, kevlar, glass, etc.) to suit different applications.  In a polymer matrix composite material, the matrix itself is not ductile like metal. Instead, it tends to be soft but very tough.  Metal cutting involves plastic deformation forming chips that serve to remove heat from the point of cutting.  Conversely, when analysed at the micro level, machining of polymer matrix does not form chips, but rather a fine ‘dust’ that results from localised fracturing.  Heat is not readily transported away from the cutting edge by the matrix due to its low thermal conductivity.   The next challenge comes from the embedded fibres which are strong, stiff and highly abrasive when cut.    Different composite manufacturing methods call for use of unidirectional tape or bi-directional fabric weave layered in different directions to suit the application.   These will behave differently when being machined.
 
Figure 1: Composites can have unidirectional fibre layout, or bidirectional weave


To complicate matters more, Carbon Fibre Reinforced Plastics (CFRP) can be stacked with aluminium or titanium support in structural applications. These conditions create machining operations that need one tool to cut materials with dramatically different properties.

Grinding with variable requirements

Duncan says: “Machining of these highly abrasive and non-homogenious materials requires careful consideration of the best tool for the job, be it drilling, trimming or pocketing.  As a result, cutting tool manufacturers are continually creating new tool designs to meet this need.”
One of the most widely used composite materials is CFRP, principally due to its excellent strength to weight ratio and corrosion resistance.  Yet, in machining this material, correct tool selection is critical, otherwise a variety of quality issues can result, including:
  • Delamination, where the matrix separates from the fibre
  • Uncut fibres that remain at the cut edge
  • Spalling where larger fragments of matrix break away
  • Inconsistent cut geometry can, for example, see hole roundness fall outside acceptable tolerances
  • Hole exit burring when drilling
  • Heat damage to the matrix
  • Rapid tool wear
The consequences of these types of issues are wasted time and money from tools that rapidly wear out, but more importantly damaged or scrapped work pieces.
Today, ANCA machines are used by cutting tool manufacturers to create a variety of cutting tools for different composite machining applications.

Tool Essentials for CFRP

Firstly, composite cutting tools come in one of three different material types.  Carbide, coated carbide or PCD.  Each has its advantages. 
Carbide can be easily fashioned into any required geometry and will produce a keen cutting edge but will also be expected to wear quickly.   For that reason, it will typically only get used in manual and/or roughing operations where the accuracy of the final cut is not critical – most likely because it will be followed by a finishing cutter made of either coated carbide or PCD.  
Coated carbide similarly offers flexibility in that it can be ground into a variety of geometries, but has an additional (CVD) coating applied that can dramatically increase tool life.  The disadvantage of these tools is that it is generally considered uneconomical to resharpen them.
The third class of tools is poly-crystalline diamond (PCD) tools. The cutting edge on such tools are typically produced using an electro erosion machine, such as the ANCA EDGe, or laser ablation processes.   
 
Figure 4: ANCA EDGe machine used for PCD tool erosion
 
Figure 5: ANCA EDGe machine eroding a veined PCD drill from Sandvik Coromont

This typically will give a keener cutting edge than CVD coated tools and additionally can be resharpened, which extends the usable life of the tool.  Within PCD tools, there are three common forms.  Firstly, they can be a carbide base with brazed PCD inserts giving a shear cutting edge.   This type of tool is commonly used to produce complex step or profile tools and is most easily produced by tool manufacturers looking to enter the PCD tool market.  
 
Figure 6: PCD insert brazed onto a carbide tool base.  EDGe erosion process is used to generate an accurate corner radius profile


The next alternative is the veined PCD technology, initially developed in house by Sandvik-Coromont Spanish Fork (USA).  This can create a helical vein of PCD, co-sintered in the carbide blank.  The helical cutting edge is seen to offer a superior cutting geometry compared to that of a shear tool, and in addition coolant holes can be included through the carbide portion, which improves cutting conditions.  For these tools, the cutting edge geometry is largely defined by the PCD vein that was sintered.
Figure 7: PCD vein is co-sintered with carbide allowing generation of a helical cutting edge

The answer to this challenge is typically a solid PCD tip with a carbide body.  While these can be expensive up front, RobbJack, based in California, USA, produces such tools using rotary electro erosion process on the ANCA EDGe.  This allows complete freedom for producing any tool (drill) geometry they require.
 
Figure 8: Solid PCD tipped drills offer maximum flexibility in drill geometry for CFRP

Hole Drilling CFRP

Hole drilling is a commonly performed operation necessary to allow joining of CFRP structures. CFRP drills will have a point geometry distinct to that of metal cutting drills.  ANCA’s Toolroom software, whether applied to grinding or PCD erosion processes, allows creation of various special drill points suited to CFRP, including compound point angles and brad or W-point geometry.   Specialised drill points result in minimised delamination as the drill penetrates through the CFRP layer, maintaining hole geometry (roundness) and offering superior tool life.    

An alternative approach for hole making is milling cutters used with interpolated orbital motion.   While it’s a slower process requiring a CNC machine, it has advantages with creating larger holes or holes on curved surfaces.  In addition, the smaller thrust force reduces delamination at the exit point of the hole.

Milling CFRP

Another common cutting operation is trimming or cutting of CFRP with specialised milling cutters.   Again, coated carbide or PCD cutters are the order of the day.

For trimming or edge cuts, up-down cutters are most commonly used.  The opposing direction of the cutting edges ensures cutting forces are toward the middle of the CFRP layer, thereby reducing the likelihood of delamination.  Shallow flute depth helps increase tool rigidity.   

 

Figure 9: Compression cutters minimise damage to the CFRP cut edge with cutting forces toward the centre of the CFRP layers

Burr style routers feature many shallow flutes that have chip breaker teeth included on them. This form of cutter works to produce localised cutting forces that can effectively shear the fibres.
ANCA grinders support the manufacture of these types of tools with dedicated compression router or burr cutter software packages.  

For surface or pocket milling, down cut endmills again will create downward cutting forces that minimise surface delamination. Brazed PCD routers are also common for this application with ball or corner radius cutting edge forms which are easily produced on the ANCA EDGe.



Figure 8: ANCA’s ToolRoom software allows creation of unique tool geometries for CFRP cutting applications
 
Duncan Thompson concludes “demand for specialised composite cutting tools will only continue to increase, presenting great market opportunities for tool makers with the right knowhow and manufacturing capabilities.   With industry leading tool design software and tool manufacturing machines, ANCA continues to work closely with its customers at the cutting edge of the composite cutting tool market.”
 

20 September 2019