General-purpose roughing that clears pockets and open areas. Where the toolpath needs to ramp or helix down into the material, a separate Ramping tab covers that lead-in move.
Typical tools
End mills, ball nose mills
Controls shown for this operation
Adjustable rows are sliders you can constrain (drag the range handles, type a value, or lock it).
Read-out rows update automatically as you change the others — they show you the effect, but you don’t set them directly.
Cutting tab
Depth of cut(Ap)
Adjustable
mm / in
How deeply the tool engages into the material along its axis on each pass.
Why it matters: The single biggest lever on how much metal you remove per pass. Deeper cuts clear material faster but pile on cutting force, heat and tool deflection — push too far and you get chatter, poor finish or a broken tool.
Width of cut(Ae)
Adjustable
mm / in
How much of the tool’s diameter is engaged sideways into the material (the step-over).
Why it matters: Works hand-in-hand with depth of cut to set the cutting load. A wider engagement removes more per pass but increases side force on the tool and the part.
Tool deflection(mean)
Adjustable
microns / thou
How far the tip of the tool is predicted to bend away under cutting force.
Why it matters: A bending tool cuts where it isn’t supposed to — the result is lost accuracy, tapered walls and chatter. Tightening this limit protects dimensional accuracy and finish, especially with long or slender tools.
Break point
Adjustable
%
How close the cutting forces are to the level that would damage or snap the tool, shown as a percentage of the safe limit.
Why it matters: Your safety margin against a broken tool. 100% means you are right at the edge — keeping this lower trades a little speed for a lot of peace of mind.
Material removal rate
Read-out
cm³/min / in³/min
The volume of material the cut removes every minute.
Why it matters: A productivity read-out, not something you set directly. Watch it rise as you make the other settings more aggressive — it’s the headline number for how fast a roughing job will run.
Workholding security
Adjustable
N / lbf
The sideways force the cut exerts on the part and the fixture holding it.
Why it matters: If this force gets too high it can pull the part out of the vice or fixture mid-cut. Tightening it keeps lightly-clamped or awkward set-ups safe.
Feed per tooth
Read-out
mm/tooth
The thickness of the chip each individual cutting edge takes as it passes through the material.
Why it matters: The fundamental health metric of a cut. Too low and the edges rub instead of cut (rapid wear, heat); too high and you overload the edge. A read-out here that the other settings feed into.
Chip load
Adjustable
mm / in
The thickness of the chip being removed.
Why it matters: Drives tool life, heat and finish. The explorer keeps it in a healthy band for the tool and material; constrain it if you have a preferred chip load for your tooling.
Feed rate
Adjustable
mm/min
How fast the tool travels through the material (the table feed).
Why it matters: The speed you actually feel on the shop floor. Faster feeds finish the job sooner but raise cutting force, heat and the load on the tool.
Surface speed
Adjustable
m/min / ft/min
The speed of the cutting edge as it sweeps past the material (the cutting speed, Vc).
Why it matters: Set by the material and tool coating — it’s the main driver of cutting heat and tool life. Together with the tool diameter it determines the spindle speed.
Spindle speed
Adjustable
rpm
How fast the spindle turns.
Why it matters: Derived from the surface speed and the tool’s diameter. Constrain it if your machine has a sweet spot or a maximum you need to respect.
Spindle power(mean)
Adjustable
kW / hp
The average power the cut draws from the spindle.
Why it matters: Has to stay within what your machine’s spindle can deliver. Lowering the limit keeps heavier cuts within reach of smaller machines.
Spindle torque
Adjustable
Nm / ft lb
The twisting force at the spindle.
Why it matters: Matters most for heavy cuts at low rpm, where torque rather than power is the limit. Keep it inside your machine’s torque curve.
Ramping tab
Depth of cut(Ap)
Read-out
mm / in
How deeply the tool engages into the material along its axis on each pass.
Why it matters: The single biggest lever on how much metal you remove per pass. Deeper cuts clear material faster but pile on cutting force, heat and tool deflection — push too far and you get chatter, poor finish or a broken tool.
Width of cut(Ae)
Read-out
mm / in
How much of the tool’s diameter is engaged sideways into the material (the step-over).
Why it matters: Works hand-in-hand with depth of cut to set the cutting load. A wider engagement removes more per pass but increases side force on the tool and the part.
Tool deflection(mean)
Adjustable
microns / thou
How far the tip of the tool is predicted to bend away under cutting force.
Why it matters: A bending tool cuts where it isn’t supposed to — the result is lost accuracy, tapered walls and chatter. Tightening this limit protects dimensional accuracy and finish, especially with long or slender tools.
Break point
Adjustable
%
How close the cutting forces are to the level that would damage or snap the tool, shown as a percentage of the safe limit.
Why it matters: Your safety margin against a broken tool. 100% means you are right at the edge — keeping this lower trades a little speed for a lot of peace of mind.
Material removal rate
Read-out
cm³/min / in³/min
The volume of material the cut removes every minute.
Why it matters: A productivity read-out, not something you set directly. Watch it rise as you make the other settings more aggressive — it’s the headline number for how fast a roughing job will run.
Workholding security
Adjustable
N / lbf
The sideways force the cut exerts on the part and the fixture holding it.
Why it matters: If this force gets too high it can pull the part out of the vice or fixture mid-cut. Tightening it keeps lightly-clamped or awkward set-ups safe.
Feed per tooth
Read-out
mm/tooth / in/tooth
The thickness of the chip each individual cutting edge takes as it passes through the material.
Why it matters: The fundamental health metric of a cut. Too low and the edges rub instead of cut (rapid wear, heat); too high and you overload the edge. A read-out here that the other settings feed into.
Chip load
Adjustable
mm / in
The thickness of the chip being removed.
Why it matters: Drives tool life, heat and finish. The explorer keeps it in a healthy band for the tool and material; constrain it if you have a preferred chip load for your tooling.
Surface speed
Adjustable
m/min / ft/min
The speed of the cutting edge as it sweeps past the material (the cutting speed, Vc).
Why it matters: Set by the material and tool coating — it’s the main driver of cutting heat and tool life. Together with the tool diameter it determines the spindle speed.
Spindle speed
Adjustable
rpm
How fast the spindle turns.
Why it matters: Derived from the surface speed and the tool’s diameter. Constrain it if your machine has a sweet spot or a maximum you need to respect.
Spindle power(mean)
Adjustable
kW / hp
The average power the cut draws from the spindle.
Why it matters: Has to stay within what your machine’s spindle can deliver. Lowering the limit keeps heavier cuts within reach of smaller machines.
Spindle torque
Adjustable
Nm /lb ft
The twisting force at the spindle.
Why it matters: Matters most for heavy cuts at low rpm, where torque rather than power is the limit. Keep it inside your machine’s torque curve.
Plunge feed rate
Read-out
mm/min in /min
The resulting straight-line speed of the tool plunging into the material.
Why it matters: A read-out of how fast the tool is travelling as it enters the cut, derived from the feed-per-revolution and the spindle speed.
Ramp feed rate
Read-out
mm/min / in/min
The feed used during the angled or helical move that eases the tool into the material.
Why it matters: A read-out for the lead-in. Ramping in gently protects the tool from the shock of plunging straight down into solid stock.
Ramp angle
Adjustable
degrees
How steeply the tool descends as it ramps or helixes into the material.
Why it matters: Shallower angles are kinder to the tool but take longer to reach depth; steeper angles get there faster but load the tool tip more.
Bore diameter
Adjustable
mm / in
The finished diameter produced by the helical / boring path.
Why it matters: Defines the hole or bore the tool will circle out. Constrain it to hit the exact bore size you need.