Horizontal Clearing/Finishing reference

The Horizontal strategy is applicable for roughing and finishing operations.

3d horizontal strategy

Manufacture > Milling > 3D > Horizontal horizontal icon

This strategy automatically detects all the flat areas of the part and clears them with an offsetting path in the same way as the Pocket Clearing strategy.

When the flat area is shelved above the surrounding areas, the cutter moves beyond the flat areas to clean the edges.

There is an option to cut down to the horizontal face in stages, which means this strategy is a combination of both roughing and finishing strategies.

tool tab icon Tool tab settings

3d horizontal clearing dialog tool tab

Coolant

Select the type of coolant used with the machine tool. Not all types will work with all machine postprocessors.

Feed & Speed

Spindle and Feedrate cutting parameters.

Shaft & Holder

When enabled, this provides additional controls for collision handling. Collision detection can be done for both the tool shaft and holder, and they can be given separate clearances. Choose between several modes, depending on the machining strategy.

This function increases the number of calculations that need to be performed. This may effect the performance of your system on very large projects.

Shaft and Holder Modes

shaft and holder mode diagram - disabled

shaft and holder mode diagram - pull away

shaft and holder mode diagram - detect length

Settings

geometry tab icon Geometry tab settings

3d horizontal clearing dialog geometry tab

Machining Boundary

Boundaries mode specifies how the toolpath boundary is defined. The following images are shown using a 3D Radial toolpath.

radial boundary mode diagram

Example 1

radial boundary mode diagram

Example 2

Boundary modes:

boundary mode diagram - bounding box

Bounding box

boundary mode diagram - silhouette

Silhouette

boundary mode diagram - silhouette

Selection

Tool Containment

Use tool containment to control the tools' position in relation to the selected boundary or boundaries.

Inside

The entire tool stays inside the boundary. As a result, the entire surface contained by the boundary might not be machined.

tool containment diagram - inside

Inside

Center

The boundary limits the center of the tool. This setting ensures that the entire surface inside the boundary is machined. However, areas outside the boundary or boundaries might also be machined.

tool containment diagram - center

Center

Outside

The toolpath is created inside the boundary, but the tool edge can move on the outside edge of the boundary.

tool containment diagram - outside

Outside

To offset the boundary containment, use the Additional Offset parameter.

Additional Offset

The additional offset is applied to the selected boundary/boundaries and tool containment.

A positive value offsets the boundary outwards unless the tool containment is Inside, in which case a positive value offsets inwards.

boundary offset diagram - inward

Negative offset with tool center on boundary

boundary offset diagram - none

No offset with tool center on boundary

boundary offset diagram - outward

Positive offset with tool center on boundary

To ensure that the edge of the tool overlaps the boundary, select the Outside tool containment method and specify a small positive value.

To ensure that the edge of the tool is completely clear of the boundary, select the Inside tool containment method and specify a small positive value.

Tool Orientation

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:

Model

Enable to override the model geometry (surfaces/bodies) defined in the setup.

Include Setup Model

Enabled by default, the model selected in the setup is included in addition to the model surfaces selected in the operation. If you disable this checkbox, then the toolpath is generated only on the surfaces selected in the operation.

heights tab icon Heights tab settings

3d horizontal clearing dialog heights tab

Clearance Height

The Clearance height is the first height the tool rapids to on its way to the start of the tool path.

clearance height diagram

Clearance Height

Clearance Height Offset

The Clearance Height Offset is applied and is relative to the Clearance height selection in the above drop-down list.

Retract Height

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 diagram

Retract Height

Retract Height Offset

Retract Height Offset is applied and is relative to the Retract height selection in the above drop-down list.

Top Height

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.

retract height diagram

Top Height

Top Offset

Top Offset is applied and is relative to the Top height selection in the above drop-down list.

Bottom Height

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 diagram

Bottom Height

Bottom Offset

Bottom Offset is applied and is relative to the Bottom height selection in the above drop-down list.

passes tab icon Passes tab settings

3d horizontal clearing dialog passes tab

Tolerance

The machining tolerance is the sum of the tolerances used for toolpath generation and geometry triangulation. Any additional filtering tolerances must be added to this tolerance to get the total tolerance.

   
tolerance loose tolerance tight
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.

Manual Stepover

Enable to set the stepover manually.

Maximum Stepover

Specifies the maximum stepover value.

Minimum Stepover

Specifies the minimum stepover.

Minimum Cutting Radius

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.

     
cut radius 0.0   cut radius 0.07
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.
Note: Setting this parameter leaves more material in internal corners requiring subsequent rest machining operations with a smaller tool.

Use Morphed Spiral Machining

Enable to create a constant spiral move toolpath for the pocket. This can provide a smooth run on the machine.

morphed spiral machining diagram - standard 2d pocket toolpath

Standard 2D pocket toolpath

morphed spiral machining diagram - morphed spiral 2d pocket toolpath

Morphed spiral 2D pocket toolpath

Direction

The Direction option lets you control if Fusion should try to maintain either Climb or Conventional milling.

Related: Depending on the geometry, it is not always possible to maintain climb or conventional milling throughout the entire toolpath.

Climb

Select Climb to machine all the passes in a single direction. When this method is used, Fusion attempts to use climb milling relative to the selected boundaries.

direction diagram - climb milling

Climb

Conventional

This reverses the direction of the toolpath compared to the Climb setting to generate a conventional milling toolpath.

direction diagram - conventional milling

Conventional

Allow Stepover Cusps

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 diagram - off

Allow stepover cusps disabled

allow stepover cusps diagram - on

Allow stepover cusps enabled

Above - Pocket machined with a 3/8" bullnose end mill @ 0.25" maximum stepover.

Smoothing Deviation

The maximum amount of smoothing applied to the roughing passes. Use this parameter to avoid sharp corners in the toolpath.

smoothing deviation diagram

Multiple Depths

Enable to do multiple depth cuts.

Multiple Depths are used to create multiple incremental Z offset passes in many of the 3D finishing strategies and are useful for removing a fixed amount of stock using several passes. The following images are shown with 3D Parallel.

axial offset pass diagram - single pass

Disabled

axial offset pass diagram - 3 passes

three stepdowns

Maximum Stepdown

Specifies the maximum stepdown between Z-levels.

Number of Stepdowns

Specifies the desired number of stepdowns.

Order by Depth

When enabled, this orders the cuts of multiple contours or cavities by Z level.

   
modeled cavities cuts by z level
Model with multiple

cavity selections
All cavities

cut by Z level

Stock to Leave

stock to leave diagram - positive

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.

stock to leave diagram - none

None

No Stock to Leave - Remove all excess material up to the selected geometry.

stock to leave diagram - negative

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.

Radial (wall) Stock to Leave

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.

stock to leave diagram - radial

Radial stock to leave

stock to leave diagram - both

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.

Axial (floor) Stock to Leave

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.

stock to leave diagram - axial

Axial stock to leave

stock to leave diagram - both

Both radial and 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.

Fillets

Enable to enter a fillet radius.

Fillet Radius

Specify a fillet radius.

Smoothing

Smooths the toolpath by removing excessive points and fitting arcs where possible within the given filtering tolerance.

   
smoothing off smoothing on
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.

Smoothing Tolerance

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.

Note: Total tolerance, or the distance the toolpath can stray from the ideal spline or surface shape, is the sum of the cut Tolerance and Smoothing Tolerance. For example, setting a cut Tolerance of .0004 in and Smoothing Tolerance of .0004 in means the toolpath can vary from the original spline or surface by as much as .0008 in from the ideal path.

Feed Optimization

Specifies that the feed should be reduced at corners.

Maximum Directional Change

Specifies the maximum angular change allowed before the feedrate is reduced.

Reduced Feed Radius

Specifies the minimum radius allowed before the feed is reduced.

Reduced Feed Distance

Specifies the distance to reduce the feed before a corner.

Reduced Feedrate

Specifies the reduced feedrate to be used at corners.

Only Inner Corners

Enable to only reduce the feedrate on inner corners.

linking tab icon Linking tab settings

3d horizontal clearing dialog linking tab

Retraction Policy

Controls how the tool moves between cutting passes. The following images are shown using the Flow strategy.

For CNC machines that do not support linearized rapid moves, the post processor can be modified to convert all G0 moves to high-feed G1 moves. Contact technical support for more information or instructions how to modify post processors as described.

High Feedrate Mode

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.

High Feedrate

The feedrate to use for rapids movements output as G1 instead of G0.

Allow Rapid Retract

When enabled, retracts are done as rapid movements (G0). Disable to force retracts at lead-out feedrate.

Safe Distance

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 safe distance is large enough to prevent any collisions.

Maximum Stay-Down Distance

Specifies the maximum distance allowed for stay-down moves.

maximum staydown distance diagram - 1 inch

1" Maximum stay-down distance

maximum staydown distance diagram - 2 inches

2" Maximum stay-down distance

Lift Height

Specifies the lift distance during repositioning moves.

lift height diagram - 0

Lift height 0

lift height diagram - .1 inch

Lift height .1 in

Horizontal Lead-In Radius

Specifies the radius for horizontal lead-in moves.

entry radius diagram

Horizontal lead-in radius

Vertical Lead-In Radius

The radius of the vertical arc smoothing the entry move as it goes from the entry move to the toolpath itself.

entry radius diagram - vertical

Vertical lead-in radius

Horizontal Lead-Out Radius

Specifies the radius for horizontal lead-out moves.

exit radius diagram

Horizontal lead-out radius

Vertical Lead-Out Radius

Specifies the radius of the vertical lead-out.

exit radius diagram - vertical

Vertical lead-out radius

Ramp Type

Specifies how the cutter moves down for each depth cut.

ramp type diagram - predrill

Predrill

Note: To use the Predrill option, Predrill location(s) must be defined.

ramp type diagram - plunge

Plunge

ramp type diagram - zig-zag

Zig-Zag

Notice the smooth transitions on the Zig-Zag ramp type.

ramp type diagram - profile

Profile

ramp type diagram - smooth profile

Smooth Profile

ramp type diagram - helix

Helix

Allow Plunging Outside Stock

Instead of machining the material inside the contour of a selected area, enabling this parameter allows you to remove the material outside the selected contour, by picking an additional stock contour.

Disable this parameter to force ramping in stock.

Ramping Angle (deg)

Specifies the maximum ramping angle.

Maximum Ramp Stepdown

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.

Ramp Clearance Height

Height of ramp over the current stock level.

Ramp Radial Clearance

Specifies the minimum distance to the contour for the lead-in helix.

Helical Ramp Diameter

Specifies the helical ramp diameter.

Minimum Ramp Diameter

Specifies the minimum ramp diameter.

Predrill positions

Selection button to choose predrill positions.

Entry positions

Selection button to choose entry positions.