2D Pocket is a roughing operation with options for creating a finish pass. You can clear a cavity, open pocket or the area around a boss. The toolpath will resemble the shape of the boundary being machined. The machining area can be selected from Edges, Sketches or a Solid face. Includes options for taper walls and Pre-drilling entry positions.
Manufacture > Milling > 2D > 2D Pocket
Select the type of coolant used with the machine tool. Not all types will work with all machine postprocessors.
Spindle and Feedrate cutting parameters.
Select Faces, Edges or Sketches. You can remove stock from the inside of a pocket or the outside of a standing boss.
|
Select any Face, Edge or Sketch to define the machining boundary. Use Edge selection for areas with holes or pockets inside of pockets. For standing bosses select the outer boundary of the boss and check the Stock Contours option shown below. The toolpath will be calculated between the selected boundary and the outer stock area.
Select Faces, Edges or Sketches. Use Edge selection for areas with holes or pockets inside of pockets.
|
When selecting an open pocket to machine, the chains of the selection extend to the stock boundary in a way that is defined by an extension method to create a closed boundary. The closed boundary is required to generate a toolpath. If the chains intersect each other before reaching the stock boundary, then there is no closed boundary and toolpath calculation fails.
Example showing successful toolpath generation over an open pocket by using a closed boundary:
1) Open pocket to machine | 2) Chain selection extending to stock boundary |
3) Closed boundary defined | 4) Resulting toolpath generated |
The extension method types are:
The extension method to select depends on the model geometry. Tangent is the default extension method and in cases where it is not appropriate, then Closest boundary is the next recommended method to use.
Tangent extension method | Closest boundary extension method | Parallel extension method |
When checked, the toolpath is calculated to consider the boundaries of the defined Stock or a selected boundary. The default boundary is the Stock box specified in the Setup. You can also select Edges from the model or a Sketch boundary. This provides additional clearance for the Lead in and Lead out moves. This can limit or extend the stock machining area. Leave unchecked for closed boundary pockets.
Stock Selections - Select a closed boundary to define the machining area. No selection is needed to machine the Stock box specified in the Setup. Selecting a boundary larger than the stock extends the cutting area. This can be useful for irregular stock sizes. The selected machining boundary can be any shape.
Select Edges or Sketches to define the cutting boundary.
Note: This is not a containment boundary, since the tool will approach from outside the selected area. |
Contour arrows point clockwise for outer-contour selections and point counter-clockwise for inner-contour selections to maintain a climb cut. You can click an arrow to change the cut direction.
Arrow pointing clockwise |
Outer-contour cut |
Arrow pointing counter-clockwise |
Inner-contour cut |
Limits the operation to just remove material that a previous tool or operation could not remove.
Rest Machining ON |
Rest Machining OFF |
Specifies the diameter of the rest material tool.
Specifies the corner radius of the rest material tool.
Specifies how the tool orientation is determined using a combination of triad orientation and origin options.
The Orientation drop-down menu provides the following options to set the orientation of the X, Y, and Z triad axes:
The Origin drop-down menu offers the following options for locating the triad origin:
The Clearance height is the first height the tool rapids to on its way to the start of the tool path.
Clearance Height
The Clearance Height Offset is applied and is relative to the Clearance height selection in the above drop-down list.
Retract height sets the height that the tool moves up to before the next cutting pass. Retract height should be set above the Feed height and Top. Retract height is used together with the subsequent offset to establish the height.
Retract Height
Retract Height Offset is applied and is relative to the Retract height selection in the above drop-down list.
Feed height sets the height that the tool rapids to before changing to the feed/plunge rate to enter the part. Feed height should be set above the Top. A drilling operation uses this height as the initial feed height and the retract peck height. Feed height is used together with the subsequent offset to establish the height.
Feed Height
Feed Height Offset is applied and is relative to the Feed height selection in the above drop-down list.
Top height sets the height that describes the top of the cut. Top height should be set above the Bottom. Top height is used together with the subsequent offset to establish the height.
Top Height
Top Offset is applied and is relative to the Top height selection in the above drop-down list.
Bottom height determines the final machining height/depth and the lowest depth that the tool descends into the stock. Bottom height needs to be set below the Top. Bottom height is used together with the subsequent offset to establish the height.
Bottom Height
Bottom Offset is applied and is relative to the Bottom height selection in the above drop-down list.
The tolerance used when linearizing geometry such as splines and ellipses. The tolerance is taken as the maximum chord distance.
Loose Tolerance .100 | Tight Tolerance .001 |
CNC machine contouring motion is controlled using line G1 and arc G2 G3 commands. To accommodate this, Fusion approximates spline and surface toolpaths by linearizing them creating many short line segments to approximate the desired shape. How accurately the toolpath matches the desired shape depends largely on the number of lines used. More lines result in a toolpath that more closely approximates the nominal shape of the spline or surface.
Data Starving
It is tempting to always use very tight tolerances but there are trade-offs including longer toolpath calculation times, large G-code files, and very short line moves. The first two are not much of a problem because Fusion calculates very quickly and most modern controls have at least 1MB of RAM. However, short line moves, coupled with high feedrates, may result in a phenomenon known as data starving.
Data starving occurs when the control becomes so overwhelmed with data that it cannot keep up. CNC controls can only process a finite number of lines of code (blocks) per second. That can be as few as 40 blocks/second on older machines and 1,000 blocks/second or more on a newer machine like the Haas Automation control. Short line moves and high feedrates can force the processing rate beyond what the control can handle. When that happens, the machine must pause after each move and wait for the next servo command from the control.
This setting determines the side of the toolpath from which the tool center is offset. Choose between Left (climb milling) sideways compensation or Right (conventional milling) sideways compensation.
Left (climb milling) Climb Milling |
Right (conventional milling) Conventional Milling |
Climb milling can be thought of as the cutter ''rolling along'' the surface that it is cutting. This generally gives a better finish in most metals, but requires good machine rigidity. Using this method, chips start at maximum thickness and get thinner towards the end of the cut, meaning more heat in the chip and less in the part.
With conventional milling, the cutter is ''rotating away'' from the surface it is cutting. This method is more commonly used with manual or less rigid machines. It does have some advantages, and can even give a better finish when machining certain materials including some woods.
Defines the smallest toolpath radius to generate in a sharp corner. Minimum Cutting Radius creates a blend at all inside sharp corners.
Forcing the tool into a sharp corner, or a corner where the radius is equal to the tool radius, can create chatter and distort the surface finish.
Set to Zero - The toolpath is forced into all inside sharp corners. | Set to 0.07 in - The toolpath will have a blend of .070 radius in all sharp corners. |
Enable to perform finishing passes using the side of the tool.
With Finishing passes |
Without Finishing passes |
Specifies the number of finishing passes.
Shown with three finishing passes
The maximum distance between finishing passes.
Forces a full lead in and out on every finishing pass.
Enabled |
Disabled |
The feedrate used for the final finishing pass.
Enable to perform the final finishing pass twice to remove stock left due to tool deflection.
The finishing overlap is the distance that the tool passes beyond the entry point before leading out. Specifying a finishing overlap ensures that the material at the entry point is properly cleared.
No finishing overlap |
0.25" finishing overlap |
Specifies that features are to be machined in the order in which they were selected. When unselected, Fusion optimizes the cut order.
Specifies that the operation uses both Climb and Conventional milling to machine open profiles.
Specifies the maximum horizontal stepover between passes.
Adaptive clearing |
Legacy 2D clearing |
Enable to create a constant spiral move toolpath for the pocket. This can provide a smooth run on the machine.
Standard 2D pocket toolpath |
Morphed spiral 2D pocket toolpath |
When programming flat faces with a tool that has a radius in the corner, a cusp (or Scallop) can be produced between stepovers.
By default, the Maximum stepover value is overridden to insure that no stepover cusps are produced.
Allow stepover cusps disabled |
Allow stepover cusps enabled |
Above - Pocket machined with a 3/8" bullnose end mill @ .25" maximum stepover.
The maximum amount of smoothing applied to the roughing passes. Use this parameter to avoid sharp corners in the toolpath.
When selected multiple depths can be taken.
With Multiple Depth cuts |
Without Multiple Depth cuts |
Specifies the distance for the maximum stepdown between Z-levels. The maximum stepdown is applied to the full depth, less any remaining stock and finish pass amounts.
The number of finishing passes using the bottom of the tool.
Shown with three finishing passes
The size of each stepdown in the finishing passes.
Finishing stepdown
Specifies the taper angle of the walls.
Defining a slope angle can be used to machine features with a 2D strategy that would have otherwise required a 3D strategy.
Slope angle @ 0 degrees |
Slope angle @ 45 degrees |
Geometry Selection
Bottom Selection |
Top Selection |
Enable to create equal distances between machining passes.
Example: Suppose you are machining a profile with a depth of 23 mm and a maximum stepdown = 10 mm.
When enabled, this orders the cuts of multiple contours or cavities by Z level.
Model with multiple cavity selections |
All cavities cut by Z level |
When enabled, each roughing and finishing step is machined to the full depth before moving to the next step.
Disabled |
Enabled |
Positive Positive Stock to Leave - The amount of stock left after an operation to be removed by subsequent roughing or finishing operations. For roughing operations, the default is to leave a small amount of material. |
None No Stock to Leave - Remove all excess material up to the selected geometry. |
Negative Negative Stock to Leave - Removes material beyond the part surface or boundary. This technique is often used in Electrode Machining to allow for a spark gap, or to meet tolerance requirements of a part. |
The Radial Stock to Leave parameter controls the amount of material to leave in the radial (perpendicular to the tool axis) direction, i.e. at the side of the tool.
Radial stock to leave |
Radial and axial stock to leave |
Specifying a positive radial stock to leave results in material being left on the vertical walls and steep areas of the part.
For surfaces that are not exactly vertical, Fusion interpolates between the axial (floor) and radial stock to leave values, so the stock left in the radial direction on these surfaces might be different from the specified value, depending on surface slope and the axial stock to leave value.
Changing the radial stock to leave automatically sets the axial stock to leave to the same amount, unless you manually enter the axial stock to leave.
For finishing operations, the default value is 0 mm / 0 in, i.e. no material is left.
For roughing operations, the default is to leave a small amount of material that can then be removed later by one or more finishing operations.
Negative stock to leave
When using a negative stock to leave, the machining operation removes more material from your stock than your model shape. This can be used to machine electrodes with a spark gap, where the size of the spark gap is equal to the negative stock to leave.
Both the radial and axial stock to leave can be negative numbers. However, the negative radial stock to leave must be less than the tool radius.
When using a ball or radius cutter with a negative radial stock to leave that is greater than the corner radius, the negative axial stock to leave must be less than or equal to the corner radius.
The Axial Stock to Leave parameter controls the amount of material to leave in the axial (along the Z-axis) direction, i.e. at the end of the tool.
Axial stock to leave |
Specifying a positive axial stock to leave results in material being left on the shallow areas of the part.
For surfaces that are not exactly horizontal, Fusion interpolates between the axial and radial (wall) stock to leave values, so the stock left in the axial direction on these surfaces might be different from the specified value depending on surface slope and the radial stock to leave value.
Changing the radial stock to leave automatically sets the axial stock to leave to the same amount, unless you manually enter the axial stock to leave.
For finishing operations, the default value is 0 mm / 0 in, i.e. no material is left.
For roughing operations, the default is to leave a small amount of material that can then be removed later by one or more finishing operations.
Negative stock to leave
When using a negative stock to leave the machining operation removes more material from your stock than your model shape. This can be used to machine electrodes with a spark gap, where the size of the spark gap is equal to the negative stock to leave.
Both the radial and axial stock to leave can be negative numbers. However, when using a ball or radius cutter with a negative radial stock to leave that is greater than the corner radius, the negative axial stock to leave must be less than or equal to the corner radius.
Smooths the toolpath by removing excessive points and fitting arcs where possible within the given filtering tolerance.
Smoothing Off | Smoothing On |
Smoothing is used to reduce code size without sacrificing accuracy. Smoothing works by replacing collinear lines with one line and tangent arcs to replace multiple lines in curved areas.
The effects of smoothing can be dramatic. G-code file size may be reduced by as much as 50% or more. The machine will run faster and more smoothly and surface finish improves. The amount of code reduction depends on how well the toolpath lends itself to smoothing. Toolpaths that lay primarily in a major plane (XY, XZ, YZ), like parallel paths, filter well. Those that do not, such as 3D Scallop, are reduced less.
Specifies the smoothing filter tolerance.
Smoothing works best when the Tolerance (the accuracy with which the original linearized path is generated) is equal to or greater than the Smoothing (line arc fitting) tolerance.
Specifies that the feed should be reduced at corners.
Specifies the maximum angular change allowed before the feedrate is reduced.
Specifies the minimum radius allowed before the feed is reduced.
Specifies the distance to reduce the feed before a corner.
Specifies the reduced feedrate to be used at corners.
Enable to only reduce the feedrate on inner corners.
Specifies when rapid movements should be output as true rapids (G0) and when they should be output as high feedrate movements (G1).
This parameter is usually set to avoid collisions at rapids on machines which perform "dog-leg" movements at rapid.
The feedrate to use for rapids movements output as G1 instead of G0.
When enabled, retracts are done as rapid movements (G0). Disable to force retracts at lead-out feedrate.
Minimum distance between the tool and the part surfaces during retract moves. The distance is measured after stock to leave has been applied, so if a negative stock to leave is used, special care should be taken to ensure that the safe distance is large enough to prevent any collisions.
When enabled, the strategy avoids retracting when the distance to the next area is below the specified stay-down distance.
Specifies the maximum distance allowed for stay-down moves.
1" Maximum stay-down |
2" Maximum stay-down distance |
Specifies the lift distance during repositioning moves.
Lift height 0 |
Lift height .1 in |
Enable to generate a lead-in.
Lead-in
Specifies the radius for horizontal lead-in moves.
Horizontal lead-in radius
Specifies the sweep of the lead-in arc.
Sweep angle @ 90 degrees
Sweep angle @ 45 degrees
Specifies the length of the linear lead-in move for which to activate radius compensation in the controller.
Linear lead-in distance
Replaces tangential extensions of lead-in/lead-out arcs with a move perpendicular to the arc.
Shown with Perpendicular entry/exit
Example: A bore that has lead arcs that are as large as possible (the larger the arc the less chance of dwell mark), and where a tangent linear lead is not possible because it would extend into the side of the bore.
The radius of the vertical arc smoothing the entry move as it goes from the entry move to the toolpath itself.
Vertical lead-in radius
Enable to generate a lead-out.
Lead-out
Specifies that the lead-out definition should be identical to the lead-in definition.
Specifies the length of the linear lead-out move for which to deactivate radius compensation in the controller.
Linear lead-out distance
Specifies the radius for horizontal lead-out moves.
Horizontal lead-out radius
Specifies the radius of the vertical lead-out.
Vertical lead-out radius
Specifies the sweep of the lead-out arc.
Replaces tangential extensions of lead-in/lead-out arcs with a move perpendicular to the arc.
Shown with Perpendicular entry/exit
Example: A bore that has lead arcs that are as large as possible (the larger the arc the less chance of dwell mark) and where a tangent linear lead is not possible because it would extend into the side of the bore.
Specifies how the cutter moves down for each depth cut.
Plunge Outside Stock |
Zig-Zag Notice the smooth transitions on the Zig-Zag ramp type. |
Predrill To use the Predrill option, Predrill location(s) must be defined. |
Profile |
Plunge |
Smooth Profile |
Helix |
Specifies the maximum ramping angle of the helix during the cut.
Creates a conical helix entry into the part. Excellent for chip clearance.
Specifies the maximum stepdown per revolution on the ramping profile. This parameter allows the tool load to be constrained when doing full-width cuts during ramping.
The Height above the stock where the helix start its ramping move.
The maximum diameter to use for a helical entry into the cavity.
An optimal value causes the tool to overlap it's center, while still creating the maximum helical bore for the entry into the cavity. The goal is for good chip evacuation. If the value is bigger than the diameter of the tool it can leave a boss standing in the center of the helix.
Value of 1.8 x the Dia. |
Value of 0.8 x the Dia. |
The smallest Helix Ramp Diameter that is acceptable.
This value should always be smaller than the Helix Ramp Diameter, so the system can calculate a range that fits the available pocket or channel. Smaller diameters can reduce the chip evacuation, create jerking machine motion and can cause tool breakage.
Select points where holes have been drilled to provide clearance for the cutter to enter the material.
Select geometry near the location where you want the tool to enter.