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By using our site, you agree to our collection of information through the use of cookies. To learn more, view our Privacy Policy. Solidcam 2017 fanuc post free download browse Academia. Nurul Zakiah Zamri Tan. CNC Меня acronis true image 2017 full version crack free считаю integrate with Rapid Prototyping is a method that has been developed which enables automatic generation of process plans from downlosd geometric image of component.

Two user-friendly programs were developed using Visual Basic to generate control code for a wax droplet RP system previously developed. Journal of Computing and Information Science in Engineering. Jordan Smith. Ioni Jhonnie. Lupita Barredo. Manoj S. Ivan Nava Bustamante. Habibur Rahman. SolidCAM is the manufacturing suite for easiest, fastest, most efficient CNC computer numerical control simulation solidcam 2017 fanuc post free download programming facility that can be done directly inside SolidWorks.

It provides a seamless single window integration and full associativity with the SolidWorks model. The iMachining technology uses intelligent, patented algorithms for specific operations to optimize the tool path, reduce machining solidcam 2017 fanuc post free download, tool wear, etc.

A great variety of machining operations on different stock objects for producing various products can be easily defined by using this suite which results in increased flexibility. The simulation process makes it possible to observe the operations in real time conditions and makes the G-code flawless for physical operation. In this paper, SolidCAM iMachining is studied and the detailed procedures of the machining process of a spur gear from stock material are described step by step by using SolidCAM 2D iMachining technology.

After the steps are defined, the whole process is simulated in various modes. Finally, the G-codes are automatically generated for the practical use in CNC machine. SolidCAM helps understand the concept, operation and importance of using CAM software in modern day manufacturing industries. Moreover, solidcam 2017 fanuc post free download using SolidCAM the steps of operation, parameter details can be set solidcam 2017 fanuc post free download a way to save time, cost, tool lives, etc.

Opu Raihan. Jovan Vukman. Ricardo Chegwin Hillembrand. Log in with Facebook Log in with Google. Remember me on this computer. Enter the email address you signed up with and we’ll email you a reset link. Need an account? Click here to sign up. Download Free PDF. Soliidcam Cristian. Introduction 1 1. Related Papers. Function Manual Digitizing. Http://replace.me/12586.txt Contents 1.

Introduction 1. SolidCAM 2. This course covers the basic concepts of SolidCAM 2. Once you have developed a good foundation in basic skills, you can refer to the online help for information on the less frequently used options. Course design This course is designed around a task-based approach to training. With the guided exercises you will learn the commands and options necessary to complete a machining task. The theoretical explanations are embedded into these exercises to give an overview of the SolidCAM 2.

Poet this training book This training frew is intended to be used both in a classroom environment under the guidance of an experienced instructor and as self-study material. It contains fanuf number of laboratory exercises to enable you to apply and practice the material covered by the guided exercises. The laboratory exercises do not contain step-by-step instructions. About the CD The CD supplied together with this book contains copies of various files that are used throughout this course.

The Exercises folder contains the files that are required for guided and laboratory exercises. The Built Parts folder inside the Exercises contains the final manufacturing projects solidxam each exercise.

Copy the complete Exercises folder on your computer. The SolidWorks files used for the exercises were prepared with SolidWorks If you are running on a different version of Windows, you may notice differences in the appearance of the menus and windows. These differences do not affect the performance soludcam the software.

For example, нажмите сюда the Change to opposite button. Define CoordSys Position The mouse icon and numbered sans serif bold text indicate the beginning of the exercise action. This style combined with the lamp icon is used for Explanation the SolidCAM functionality explanations embedded into the guided exercises. The lamp icon is also used to emphasize notes. This includes the model name, the coordinate system position, tool options, CNC-controller, etc.

This geometry is associated with the native SolidWorks model. Technology, Tool parameters and Solidcam 2017 fanuc post free download are defined in the Operation. In short, Operation means how you want to machine. You have to define a number of Coordinate Systems that describe the positioning of the part on the CNC-machine.

Optionally, you can define the Stock model and Target model to be used for the rest material calculation. The Stock model describes the initial state of the workpiece that has to be machined. The Target model describes the one that has to be sopidcam after the machining. After every operation, SolidCAM calculates how much material was actually removed from poxt CAM-Part and how much material remains unmachined rest material.

The rest material information enables SolidCAM to automatically optimize the tool path and avoid the air cutting. Operations definition SolidCAM enables you to define a number of milling operations. During an operation definition you have to select the Geometry, choose the tool from the Part Tool Table or define a new onedefine a детальнее на этой странице strategy and a number of technological parameters.

At this stage, you have to define the CAM-Part name and location. Choosing a CNC-controller is a necessary step. The controller type influences the Coordinate System definition and the Geometry definition. SolidCAM enables you to define the stock model that describes the initial state solidcam 2017 fanuc post free download the workpiece to be machined. SolidCAM enables you to define the model of the part in its final state after the machining.

The following exercises describe the full process of the CAM-Part definition. It is recommended to go through the stages in order to understand how the CAM-Part features are built. For this purpose, you have to turn off the automatic CAM-Part definition. Click OK to confirm your microsoft visual studio 2010 ultimate vs professional free что. These settings can be turned back on at any time.

In this exercise, you have to create the CAM- Part for the cover model displayed and define the Coordinate System, the Stock model and Target model that gree necessary for the http://replace.me/7071.txt machining.

The Solidcam 2017 fanuc post free download will be used in the exercises further on. When you start to program a CAM-Part, you have to decide what workpiece you are going to use. This decision жмите the number and the type of operations that are used to reach the final part shape.

In this exercise, the box stock is used. The box dimensions include offsets from the actual model. At the next stage, you have to decide on what type of CNC-machine you are going to use 3- 4- or 5-axis. In this exercise, solidcam 2017 fanuc post free download 3-axis CNC-machine is chosen for the machining. With a CNC-machine of this type, solidcam 2017 fanuc post free download the required faces of the cover part can be machined using a single positioning.

Load the SolidWorks model Load the Exercise1. This model contains solidcaam number of features forming the solid body of the cover. You can enter the path or use the Browse button to define the location. You can give any name to identify your machining project. By default, SolidCAM uses the name of the design 217. The name is, by default, the name of the active SolidWorks document. In this case, the chosen Downolad document is loaded больше информации SolidWorks.

When the date of the original SolidWorks model is later than the date of the CAM-Part creation, this means that the SolidWorks original model has been updated. The Http://replace.me/24170.txt is defined, and its structure is solidcam 2017 fanuc post free download.

The Milling Part Data dialog box is displayed.

 
 

Post Processor Files > Solidcam turn-mill postprocesor fanuc.Post Processors

 

Start the tool definitionby clicking the Select button. Currently, the Part Tool Table is empty. Define a new tool suitable for face milling. Click the Add Milling Tool button to start the tool definition.

The new pane containing available tools is displayed. This dialog box enables you to add a new tool to the tool library choosing from thetools available for the current operation. Face millThis tool type is used for machining of large flat surfaces. A tool of thistype is defined with the parameters shown in the image.

Click the Select button to confirm the tool parameters and choose the tool for theoperation. Click the Facedepth button in the Milling levels area.

This button enables you to define the OperationLower level directly on the solid model. The depth is calculated automatically as thedifference between the Z-values of the Operation Upper and Lower levels.

The Pick Lower level dialog box isdisplayed. Select the model face as shown. The lower level value 0 is determined and displayed in the Pick Lower level dialog box. Confirm this dialog box with the button. The Face depth value is displayed in the Millinglevels area. The pink background of the edit boxmeans that the parameter is associative to themodel.

Associativity enables the selected level tobe synchronized with the solid model changes; SolidCAM automatically updates the CAM datawhen the model is modified. Define the technological parametersSwitch to the Technology page of the Face Milling Operation dialog box. In theTechnology section, choose the One Pass option. The direction and locationof the pass are calculated automaticallyaccording to the face geometry, inorder to generate an optimal toolmovement with the tool covering thewhole geometry.

Selecting the One pass optionautomatically opens the One passtab that enables you to define themachining parameters. The Extension section enables you to define the tool path extensionover the face edges.

The Face Milling operation data is saved, and the tool path is calculated. TheSimulation control panel is displayed. Switch to the SolidVerify page and startthe simulation with thebutton. The solid stock model defined in Exercise 1 is used in the SolidVerifysimulation mode. During the machining simulation process, SolidCAM subtracts the tool movements using solid Boolean operations from thesolid model of the stock.

The remaining machined stock is a solid modelthat can be dynamically zoomed or rotated. It can also be compared to thetarget model in order to show the rest material. During the simulation, you can rotate , move , or zoom themodel.

Use these options to see the machining area in details. The Single step mode can be used to simulate the next tool movement byclicking the button or by using the space bar on your keyboard. Close the simulation with the button. The Face Milling Operation dialog box isdisplayed. Close this dialog box with the Exit button. The Profile Operation dialog box isdisplayed. In this operation, the external profile ismachined. Define the GeometryThe first step of definition of each operation is the Geometry selection.

At this stage,you have to define the Geometry for the Profile operation using the solid modelgeometry. Click in the Geometry page of the Profile Operation dialog box. This dialog box enables you to add and editgeometry chains.

When this dialog box is displayed, you can select solid model entitiesfor the Geometry definition. Chain Selection OptionsYou can define the geometry by selecting edges,sketch segments and points on the contour. The following options are available:CurveThis option enables you to create a chain ofexisting curves and edges by selecting themone after the other.

Associativity: SolidCAM keeps the associativity to any edge or sketchentity. Any change made to the model or sketch automatically updatesthe selected geometry. LoopThis option enables you to select a loop by picking one of the modeledges.

Loop 2Loop Pick an edge shared by two model faces. Two faces towhich this edge belongs are determined, and their loopsare highlighted.

The first determined loop is consideredto be the primary and is highlighted with yellow color. The second loop is considered to be the secondary andis highlighted with blue color. Choose one of the loops. Click on any other edgeforming the face. You are prompted to accept the chainthat is now highlighted with yellow color. Accept thechain with the Yes button.

A closed geometry chain isdefined on this loop, and the secondary loop is rejected. Point to pointThis option enables you to connect specified points; the points areconnected by a straight line.

Associativity: SolidCAM does not keep the associativity to any selectedpoint. Any change made to the model or sketch does not update theselected geometry. You cannot select a point that is not located on aSolidWorks entity if you need to select such a point, adda planar surface under the model and select the pointson that surface.

Whenever the model is changed and synchronized,the geometry is updated with the model. Any change made to the model or sketch does notupdate the selected geometry. Automatic selection options SolidCAM automatically determines the chainentities and close the chain contour.

The Autoselect mode offers the following options:Auto-toThe chain is selected by specifying the start curve,the direction of the chain and the element up towhich the chain is created. SolidCAM enablesyou to choose any model edge, vertex or sketchentity to determine the chain end. The chain selection is terminated when the selectedend item is reached. End entityStart entitySelected chain If the chosen end item cannot be reached by the chain flow, the chaindefinition is terminated when the start chain segment is reached.

Thechain is automatically closed. End entityStart entitySelected chainThe confirmation message is displayed.

The Auto-to option is useful if you do not want to definea closed chain, but an open chain up to a certain element. Auto-general SolidCAM highlights all the entities that are connected to the last chainentity. You have to select the entity along which you want the chain tocontinue. You are prompted to identify thenext chain element when two entities on the same Z-level are connectedto the chain. Auto-Delta ZWhen you select this option, you are required to enter a positive andnegative Z-deviation into the Delta-Z dialog box.

Only entities in thisrange are identified as the next possible entity of the chain. In this exercise, the geometry must be defined as shown. The red arrow indicates the direction of the geometry.

In SolidCAM operations, thedirection of the chain geometryis used for the tool pathcalculation. In Profile milling,the tool moves in the directionof the geometry by default. Inthis exercise, the combinationof the geometry direction andthe clockwise direction of thetool revolution enables you toperform climb milling.

Tool movementdirectionGeometrydirectionTool revolutiondirectionWhen you pick the first chain entity on the solid model, SolidCAM determines the start point of the picked entity closest to the pickedposition.

The direction of the picked first chain entity is definedautomatically from the start point to the picked position. Starting pointDirectionPicked positionGeometry chainChoose the Loop option in the Chain section and click on the model edge as shown.

Notice that the pickedposition must be close to thestart point of the geometry. The red arrow indicates the direction of the selected chain. Click the secondary chain highlighted with blue color to choose it for geometrydefinition. The picked chain is now highlighted with red color, and the second chain is rejected.

The confirmation message is displayed. Confirm it with the Yesbutton. The chain icon is displayed in the Chain List section. At this stage, the Geometry is defined. Confirm the Geometry selection withthe button. The Profile Operation dialog box is displayed. Define the ToolAt this stage, you have to define the tool for the Profile milling. Switch to the Tool page of the Profile Operation dialog box and click the Select button. The Part Tool Table with the tool used in the previous operation is displayed.

Click the End Mill tool to choose it for the operation. In the Tool parameter section,under Topology, set the Diameter value to Set the Spin rate used in rough milling value to TheSpin finish used in finish milling value is automatically setto When this check box is selected, thecorresponding edit box is available so that you can edit its value. Whenthis check box is not selected, the specified Spin rate value is used forboth rough and finish machining.

Select thecheck box near the Feed finish feed rate for finish milling parameter and set the value to The Feed finish check box enables you to optionally define differentvalues for Feed XY and Feed finish. Whenthis check box is not selected, the specified Feed XY value is used forboth rough and finish machining. SolidCAM enables you to define the milling levels using the solid model data.

Upper LevelThis parameter defines the Z-level at which the machining starts. Profile DepthThis parameter defines the Z-level below which the tool does not mill. This plane is not penetrated in any milling strategy. The Pick Upper level dialogbox is displayed. The Upper Level value 0 is determinedand displayed in the Pick Upper leveldialog box. Confirm this dialog box byclicking the button. Click the Profile depth button in theMilling levels area.

The Pick Lower level dialog box is displayed. Pick the bottom edge of the model asshown. The Lower level value is determinedand displayed in the Pick Lower leveldialog box. Confirm this dialog box withthe button.

The Delta depth parameter defines the offset for the cutting depththat can be changed with its associativity preserved. The Delta depthvalue is always relative to the Profile Depth defined for the operation. Set the Delta depth value to The milling levels are defined. Define the technological parametersSwitch to the Technology page of the Profile Operation dialog box. First, you need to make sure that the tool position relative to the geometry is correct.

In the Modify section, check the Tool side option. ModifyThe Tool side option enables you to determine the tool position relativeto the geometry. Right — the tool cuts on the right side of the profile geometry. Left — the tool cuts on the left side of the profile geometry. Center — the center of the tool moves on the profile geometry nocompensation G4x can be used with this option.

Left Right CenterThe Geometry button displays the Modify Geometry dialog box thatenables you to define the modification parameters of the geometryand to choose which geometry chains are active in the operation incase of multiple chain geometry.

The chain geometry of the profileis displayed on the model with the chain direction indicated anda circle representing the tool relative to the geometry. In this case, the default Left option meets therequirements of climb milling. Click the Geometry buttonto check the tool position. Click the button in the ModifyGeometry dialog box. The ProfileOperation dialog box is displayed again.

SolidCAM enables you to perform the rough and finish machining of the profile ina single Profile operation. Select the Rough check box. Definethe Step down parameter for roughing. Step downProfile roughing is performed inconstant Z-passes. The Step downparameter defines the distancebetween each two successiveZ-levels. Step downUpperlevelProfiledepthSet the Step down to 5.

With this value, SolidCAM performs two cuts at the following Z-levels: -5, ; the lastcut is performed at the Z-level defined by Profile depth. Now you need to define the wall offset that will remain after the roughing passes. OffsetsThe Wall offset and Floor offset parameters enable you to define theallowances that remain on the walls and the floor of the machined parttill the profile finish machining.

These allowances can be removed withthe finish passes in the same Profile operation or in an additional Profileoperation with another tool. Theallowance of 0. This allowance will be removed witha separate finishing cut in the end of the profile machining. Select the Finish check box to perform the finishing of theprofile. This page enables you to define the way the tool approaches the profile and retreatsaway.

Profile Lead in and Lead outThe lead-in movement is necessary to prevent vertical entering of thetool into the material. With the lead-in strategies the tool descends to themachining level outside of the material and then horizontally penetratesthe material with the lead-in movement.

The lead-out strategy enablesyou to perform the retract movements outside the material. The length of the normal canbe set in the Normal length field.

Thedistance between the normal andmaterial is set in the Tangent extensionfield. The arcradius can be set in the Radius field. Thelength of the extension can be set in theTangent extension field. The arc angle isset in the Arc angle field. The length of the tangentcan be set in the Length field. Thedistance to the material can be set in theTangent extension field.

From this position, thetool moves on a straight line to the startpoint of the profile. When you selectthis option, the Pick button is activatedso that you can select a position directlyon the solid model. The distancebetween the point and material is set inthe Tangent extension field.

When you select thisoption, you can define a geometry of the tool approach to the material. When the Same as Lead in check box is selected, the strategy andparameters defined for Lead in are used for Lead out.

Under Lead in, choose the Arc optionfrom the list, and set the Tangentextension value to 5 and the Radius valueto 2. Under Lead out, select the Same as Leadin check box.

The definition of the basic technologicalparameters of profile milling is finished. The Profile operation data is saved, and the toolpath is calculated. Simulate the operationClick the Simulate button in the Profile Operation dialogbox.

The Simulation control panel is displayed. Switch tothe SolidVerify page and start the simulation with the Playbutton. When the simulation is finished, play the it step by step using thebutton. Since all the View options ofSolidWorks are active during the simulation, you can see the tool path fromdifferent perspectives and zoom on a certain area of the model. Close the simulation with the Exitdisplayed. The Profile Operation dialog box is Add a Pocket operationThe Pocket operation is used for the internalpocket machining.

Right-click the last definedProfile operation and choose Pocket from theAdd Milling Operation submenu. The Pocket Operation dialog box is displayed. Define the GeometryThe geometry for a Pocket operation is generally represented by closed chains.

In thisexercise, you have to define a chain using the solid model edges. Click the button in the Geometrypage to start the geometry definition. The Geometry Edit dialog box isdisplayed. Using the Loop option, define thechain as shown. Confirm the geometry definition byclicking the button. Define the ToolSwitch to the Tool page and click the Select button. The Part Tool Table is displayed.

Click the to start the tool definition. The Tool type table is displayed. In the Topology page, set the Diametervalue to 8. Define the Milling levelsSwitch to the Levels page of the PocketOperation dialog box and define upperand lower levels of machining directly onthe solid model. Define the Upper level as shown. TheUpper level value 0 is determined. Define the Pocket depth by clicking onthe pocket bottom face as shown. The Pocket depth value 8 is determined.

Set the Step down value to 4 to perform the pocketmachining in two equal steps. Define the technological parametersSwitch to the Technology page of the Pocket Operationdialog box. In the Offsets section, set the Wall offsetand the Floor offset values to 0. These offsets remainunmachined during roughing and are removed with thefurther finishing. In the Finish area, select the Wall and Floor check boxes. These options enable you to perform finishing of the Walloffset and Floor offset that remain after the roughing.

Define the machining strategy. Make sure that the defaultContour option is chosen in the Technology section. Whenthe Contour strategy is chosen, the tool moves on offsetsparallel to the pocket contour. Switch to the Contour tab to display the Contourparameters. This page enables you to define theparameters of the Contour strategy. The Min. If the given radius is too large for a specific corner, itproduces the largest possible radius at that point.

Sometimes the fillet option can leave some material. This particularly happens if the given radius is large. The tool path formsa loop in the corner, preventing anabrupt change of direction. Althoughthis produces a sharp movement by thetool, the path itself is slightly shorterthan the smooth corner option. Thiscan help cut down on machining time.

This option is not recommended for high-speed cutting. DirectionThis option enables you to choose climb or conventional milling for theroughing operation. Climb millingConventional milling Theradius of the arc is half the distance betweenthe tool path passes.

Exit materialThis option controls the tool movements between the working areas. Exit material check box notselectedWhen the tool moves from oneworking area to the next, it movesthrough the full material aroundthe island to get to the nextworking area as shown above. Connect islandsThis option enables you to keep thesame cutting direction conventional orclimb milling throughout the entire toolpath where possible.

This is particularlyimportant in high-speed cutting. Exit material check boxselectedThe tool exits the materialand travels rapidly above thematerial to the next workingarea as shown above. The leadin path is the Lead in you define. Define the strategy with which the tool is plunginginto the material during the pocket roughing.

Fromthis position, the tool moves to the pocket start point calculated bythe pocket algorithm. Click the Data button to specify the positionwhere the tool plunges into the material.

The start point must be selected using the Data button. Enter theramping angle value into the Angle edit box of the Angle rampingdialog box. SolidCAM does not check the ramping movement against the pocketcontour.

Check the tool path simulation to make sure that the tooldoes not gouge the pocket walls or islands. When the tool reaches the step down depth,it machines all the material at the step down depth. Click the Databutton to set the helical ramping parameters. The difference is that the descent is performed in a linear zigzagfashion rather than in a circular one. Choose the Helical option and click the Data button. The Helical ramping dialog box is displayed. This dialog box enables you to definethe ramping position and the related parameters for each chain used in the Pocketoperation.

Helical Ramping ParametersThe Tool step down parameter defines thedistance between each two adjacent turns of thetool helical movement. The Angle parameter defines the ramping angle. The Radius parameter defines the radius of thedescending helix. Center cuttingIf your tool has center cutting capabilities, selectthe Center cutting check box. In the Angle field,enter the descent angle that you would like thetool to follow.

In the Radius field, enter theradius of the tool path helix. The working order is as follows If the tool does not have center cutting capabilities, do not select theCenter cutting check box.

In the Tool step down field, enter the depth ofthe step down of the tool. Then it descends to thenext Tool step down. ChainsThis section displays the list of all geometry chains defined for theoperation.

All the chain entries are displayed under the Chains header. You can select chain entries in the list. When the Chains header is selected, SolidCAM displays the tool pathand default ramping positions for all of the chains. The circles representthe default helical ramping movement defined for each chain. When a chain entry is selected, SolidCAM displays the tool path and thedefault ramping position for this chain.

This position is automaticallydefined at the start position of the tool path segment relevant for thecurrent chain. You can change this position by picking a point on themodel or by entering the new position coordinates into the X, Y, Z dialogbox.

The schematic circle facilitates the definition of the position. When the position is picked, it is marked on the model witha red dot. The coordinates of the picked point are displayed in theX, Y, Z dialog box. The start position of the tool path is marked on themodel with a yellow dot. The circle of the tool path color represents thehelical movement of the tool plunging.

Tool path start positionRamping positionWhen the ramping position is defined, the tool descends into the materialat the specified ramping position with helical movements according tothe defined parameters. When it reaches the level of the first cutting pass,it moves to the start position of the tool path and performs machiningof the pocket. The Auto next button provides you with the selection mode that enablesyou to define the ramping positions for all of the chains one by one.

Confirm the dialog box with thebutton. The length of thenormal can be set in the Normal lengthfield. The distance between the normal andstart of the geometry is set in the Tangentextension field. TangentExtensionNormal Length Thearc radius can be set in the Radius field. The length of the extension can be set inthe Tangent extension field.

The distanceto the material can be set in the Tangentextension field. TangentExtensionLengthWhen the Same as Lead in check box is selected, the strategy andparameters defined for Lead in are used for Lead out. Under Lead in, choose the Arc optionfrom the list and set the Tangent extensionvalue to 3 and the Radius value to 2. The Pocket operation data is saved and the tool pathis calculated. Add a Drilling operationThis Drilling operation is used to perform thepreliminary center drilling of the four holes inthe corners of the model.

The Drilling Operation dialog box is displayed. Define the Drill geometryIn the Geometry area, click thebutton. This dialog box enables you to select the geometry for drilling directly on the solidmodel. Due to the natureof spline curves or surface boundaries, youcannot pick a center position like you couldon a circle or an arc. SolidCAM calculates thecenter position of an arc defined by threepoints positioned on the spline edges. Thisfacilitates selecting drill centers on splinesurfaces.

Four drill positions are selected. Theircoordinates are displayed in bottompart of the Drill Geometry Selectiondialog box. Click the button to confirm the geometry selection. The Drilling Operation dialogbox is displayed. Click to start a new drilling tool definition.

From theDrilling Tools section, choose the Spot drill tool for theoperation. Spot DrillThis tool type is used for center drilling and chamfering in Drillingoperations. A tool of this type is defined with the parameters shown inthe image. Click the Select button to choose the tool for the operation. Click the Data tab. Define the spin and the feed for the operation. Define the center drilling depthSwitch to the Levels page of the Drilling Operationdialog box. Click the Drill depth button and selectthe upper face of the model.

The Drill depth value 0 appears in the relevant edit box. To perform the drilling down to the specified diameter of the tool, use the Depth typeoption. The Diameter value can vary from 0 all the way up to the drill tooldiameter. A value greater than the drill tool diameter is automaticallydecreased to the drill tool diameter.

Choose the Diameter value option and set the value to 5. In this manner, the drilling is performed till the tooldiameter of 5 mm is reached at the depth of 0. The Drilling operation data is saved and the toolpath is calculated. Simulate the operationSimulate the operation in theSolidVerify simulation mode. Add a Drilling operationAdd another Drilling operation to perform the through drilling of the holes. Define the GeometryThis operation is using the geometry that was defined inthe previous center drilling operation.

Choose the Drillgeometry from the list in the Geometry area. Each geometry defined in SolidCAM has a unique name. When the geometryis being defined, it is assigned a default name that can be changed.

Usingthis name, you can choose the geometry for a specific operation. Click the Data tab in the Tool page. Define the spin and feed for the operation. Define the Drilling depthThe overall height of the model is 10 mmplus the 5 mm bottom offset defined forthe stock. The drilling has to be performeddeeper than this depth in order to enable thetool to exit from the material and performthe through drilling.

Switch to the Levels page. Define the Upper level by clicking on the top face of the model as shown. Define the Drill depth. Rotate the model and select the bottom face as shown. Since the Z- offset defined for the stock model is 5mm, set the Delta value to To perform the through drilling, choose the Fulldiameter option in the Depth type area.

With thisoption, the drilling is performed until the fulldiameter is reached at the specified drill depth. This means that the conical part of the tool exitsfrom the material. In this operation, the pecking canned cycle is used for chip breaking. With this cycle, the chip breaking is accomplished by slight retracts of the tool duringthe drilling process.

Switch to the Technology page and click the Drill cycle type button. Available drillcycles are displayed. Click the Peck button.

The cycle is chosen for the operation. Click the Data button to define the pecking parameters. The DrillOptions dialog box is displayed. Confirm the data with the OK button. The Drilling operation data is saved, and the tool path is calculated.

Simulate the operationSimulate the operation in the SolidVerify simulation mode. Since in the previous operation the drilling diameter was greater than that inthis operation, the drilling results in a chamfer on the drilled holes. Now you have successfully finished the exercise. Post Library for Autodesk Fusion Coub is YouTube for video loops. Use of 3D-CAD data in manufacturing plants is spreading for …. Re: solidcam simulate 4th axis rotation. Top posts august 3rd Top posts of august, Top posts Vi vengo a chiedere con gentilezza se qualcuno ha i post ….

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SolidCAM – Solid Platform for Manufacturing: Postprocessors

 

We create and support customized post processors in order to get working G-code to your CNC machine. If your company needs any custom продолжить processors we are happy to create these for your CNC machines. Any customizations or edits to existing post processors can also be handled by our team. Please fill out the information form and we will contact you about creating your new custom post processor to post CNC code for your exact CNC machine and controller.

Our team at Hawk Ridge Systems understand that not all businesses or organizations have the same CAM needs because everyone is working on different products with different budgets and time schedules. Our mission encompasses building strong relationships with our customers as trusted partners and not just another software tool vendor.

We aim to take the hassle out of researching amongst various CAM Post Processor tools, so you can focus on boosting your innovative products. Our list of no-charge post processors for a range of 3 axis mills and 2 axis lathes is listed below and will continue to grow. Any customizations or edits to existing post-processors can also be handled by our team. Post processors are a critical part of any CAM system. Their basic function is to translate the toolpath you see on screen to machine-readable code на этой странице referred to as G-codebut with the right post processor you can reduce machine solidcam 2017 fanuc post free download time, remove manual editing and provide more information to your operators for a faster solidcam 2017 fanuc post free download time.

Skip to primary navigation Skip solidcam 2017 fanuc post free download main content Skip to footer. MACH 4 Mill. MACH 3 Mill. Dynapath Delta Mill Mill. Thermwood Router Router. Tormach SL Lathe. We will be in touch with you shortly. Contact us and our CAM experts will answer all your questions.

 
 

Solidcam 2017 fanuc post free download.CAM AND CNC POST PROCESSORS

 
 

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Started by first off. Started by numbnutts. Started by Pat The Delta depth parameter defines the offset for the cutting depththat can be changed with its associativity preserved. The Delta depthvalue is always relative to the Profile Depth defined for the operation. Set the Delta depth value to The milling levels are defined. Define the technological parametersSwitch to the Technology page of the Profile Operation dialog box.

First, you need to make sure that the tool position relative to the geometry is correct. In the Modify section, check the Tool side option. ModifyThe Tool side option enables you to determine the tool position relativeto the geometry. Right — the tool cuts on the right side of the profile geometry.

Left — the tool cuts on the left side of the profile geometry. Center — the center of the tool moves on the profile geometry nocompensation G4x can be used with this option. Left Right CenterThe Geometry button displays the Modify Geometry dialog box thatenables you to define the modification parameters of the geometryand to choose which geometry chains are active in the operation incase of multiple chain geometry.

The chain geometry of the profileis displayed on the model with the chain direction indicated anda circle representing the tool relative to the geometry.

In this case, the default Left option meets therequirements of climb milling. Click the Geometry buttonto check the tool position. Click the button in the ModifyGeometry dialog box. The ProfileOperation dialog box is displayed again.

SolidCAM enables you to perform the rough and finish machining of the profile ina single Profile operation. Select the Rough check box. Definethe Step down parameter for roughing. Step downProfile roughing is performed inconstant Z-passes. The Step downparameter defines the distancebetween each two successiveZ-levels.

Step downUpperlevelProfiledepthSet the Step down to 5. With this value, SolidCAM performs two cuts at the following Z-levels: -5, ; the lastcut is performed at the Z-level defined by Profile depth. Now you need to define the wall offset that will remain after the roughing passes. OffsetsThe Wall offset and Floor offset parameters enable you to define theallowances that remain on the walls and the floor of the machined parttill the profile finish machining.

These allowances can be removed withthe finish passes in the same Profile operation or in an additional Profileoperation with another tool. Theallowance of 0. This allowance will be removed witha separate finishing cut in the end of the profile machining.

Select the Finish check box to perform the finishing of theprofile. This page enables you to define the way the tool approaches the profile and retreatsaway. Profile Lead in and Lead outThe lead-in movement is necessary to prevent vertical entering of thetool into the material. With the lead-in strategies the tool descends to themachining level outside of the material and then horizontally penetratesthe material with the lead-in movement.

The lead-out strategy enablesyou to perform the retract movements outside the material. The length of the normal canbe set in the Normal length field. Thedistance between the normal andmaterial is set in the Tangent extensionfield. The arcradius can be set in the Radius field. Thelength of the extension can be set in theTangent extension field.

The arc angle isset in the Arc angle field. The length of the tangentcan be set in the Length field. Thedistance to the material can be set in theTangent extension field. From this position, thetool moves on a straight line to the startpoint of the profile. When you selectthis option, the Pick button is activatedso that you can select a position directlyon the solid model.

The distancebetween the point and material is set inthe Tangent extension field. When you select thisoption, you can define a geometry of the tool approach to the material.

When the Same as Lead in check box is selected, the strategy andparameters defined for Lead in are used for Lead out.

Under Lead in, choose the Arc optionfrom the list, and set the Tangentextension value to 5 and the Radius valueto 2.

Under Lead out, select the Same as Leadin check box. The definition of the basic technologicalparameters of profile milling is finished.

The Profile operation data is saved, and the toolpath is calculated. Simulate the operationClick the Simulate button in the Profile Operation dialogbox. The Simulation control panel is displayed. Switch tothe SolidVerify page and start the simulation with the Playbutton. When the simulation is finished, play the it step by step using thebutton. Since all the View options ofSolidWorks are active during the simulation, you can see the tool path fromdifferent perspectives and zoom on a certain area of the model.

Close the simulation with the Exitdisplayed. The Profile Operation dialog box is Add a Pocket operationThe Pocket operation is used for the internalpocket machining. Right-click the last definedProfile operation and choose Pocket from theAdd Milling Operation submenu.

The Pocket Operation dialog box is displayed. Define the GeometryThe geometry for a Pocket operation is generally represented by closed chains. In thisexercise, you have to define a chain using the solid model edges. Click the button in the Geometrypage to start the geometry definition. The Geometry Edit dialog box isdisplayed. Using the Loop option, define thechain as shown. Confirm the geometry definition byclicking the button. Define the ToolSwitch to the Tool page and click the Select button.

The Part Tool Table is displayed. Click the to start the tool definition. The Tool type table is displayed. In the Topology page, set the Diametervalue to 8. Define the Milling levelsSwitch to the Levels page of the PocketOperation dialog box and define upperand lower levels of machining directly onthe solid model. Define the Upper level as shown. TheUpper level value 0 is determined. Define the Pocket depth by clicking onthe pocket bottom face as shown. The Pocket depth value 8 is determined.

Set the Step down value to 4 to perform the pocketmachining in two equal steps. Define the technological parametersSwitch to the Technology page of the Pocket Operationdialog box. In the Offsets section, set the Wall offsetand the Floor offset values to 0. These offsets remainunmachined during roughing and are removed with thefurther finishing. In the Finish area, select the Wall and Floor check boxes. These options enable you to perform finishing of the Walloffset and Floor offset that remain after the roughing.

Define the machining strategy. Make sure that the defaultContour option is chosen in the Technology section. Whenthe Contour strategy is chosen, the tool moves on offsetsparallel to the pocket contour. Switch to the Contour tab to display the Contourparameters. This page enables you to define theparameters of the Contour strategy.

The Min. If the given radius is too large for a specific corner, itproduces the largest possible radius at that point. Sometimes the fillet option can leave some material. This particularly happens if the given radius is large. The tool path formsa loop in the corner, preventing anabrupt change of direction.

Althoughthis produces a sharp movement by thetool, the path itself is slightly shorterthan the smooth corner option. Thiscan help cut down on machining time.

This option is not recommended for high-speed cutting. DirectionThis option enables you to choose climb or conventional milling for theroughing operation. Climb millingConventional milling Theradius of the arc is half the distance betweenthe tool path passes. Exit materialThis option controls the tool movements between the working areas. Exit material check box notselectedWhen the tool moves from oneworking area to the next, it movesthrough the full material aroundthe island to get to the nextworking area as shown above.

Connect islandsThis option enables you to keep thesame cutting direction conventional orclimb milling throughout the entire toolpath where possible. This is particularlyimportant in high-speed cutting. Exit material check boxselectedThe tool exits the materialand travels rapidly above thematerial to the next workingarea as shown above. The leadin path is the Lead in you define. Define the strategy with which the tool is plunginginto the material during the pocket roughing.

Fromthis position, the tool moves to the pocket start point calculated bythe pocket algorithm. Click the Data button to specify the positionwhere the tool plunges into the material.

The start point must be selected using the Data button. Enter theramping angle value into the Angle edit box of the Angle rampingdialog box. SolidCAM does not check the ramping movement against the pocketcontour. Check the tool path simulation to make sure that the tooldoes not gouge the pocket walls or islands. When the tool reaches the step down depth,it machines all the material at the step down depth.

Click the Databutton to set the helical ramping parameters. The difference is that the descent is performed in a linear zigzagfashion rather than in a circular one. Choose the Helical option and click the Data button. The Helical ramping dialog box is displayed. This dialog box enables you to definethe ramping position and the related parameters for each chain used in the Pocketoperation.

Helical Ramping ParametersThe Tool step down parameter defines thedistance between each two adjacent turns of thetool helical movement. The Angle parameter defines the ramping angle. The Radius parameter defines the radius of thedescending helix. Center cuttingIf your tool has center cutting capabilities, selectthe Center cutting check box. In the Angle field,enter the descent angle that you would like thetool to follow.

In the Radius field, enter theradius of the tool path helix. The working order is as follows If the tool does not have center cutting capabilities, do not select theCenter cutting check box. In the Tool step down field, enter the depth ofthe step down of the tool. Then it descends to thenext Tool step down. ChainsThis section displays the list of all geometry chains defined for theoperation. All the chain entries are displayed under the Chains header. You can select chain entries in the list.

When the Chains header is selected, SolidCAM displays the tool pathand default ramping positions for all of the chains. The circles representthe default helical ramping movement defined for each chain. When a chain entry is selected, SolidCAM displays the tool path and thedefault ramping position for this chain. This position is automaticallydefined at the start position of the tool path segment relevant for thecurrent chain. You can change this position by picking a point on themodel or by entering the new position coordinates into the X, Y, Z dialogbox.

The schematic circle facilitates the definition of the position. When the position is picked, it is marked on the model witha red dot. The coordinates of the picked point are displayed in theX, Y, Z dialog box. The start position of the tool path is marked on themodel with a yellow dot. The circle of the tool path color represents thehelical movement of the tool plunging. Tool path start positionRamping positionWhen the ramping position is defined, the tool descends into the materialat the specified ramping position with helical movements according tothe defined parameters.

When it reaches the level of the first cutting pass,it moves to the start position of the tool path and performs machiningof the pocket. The Auto next button provides you with the selection mode that enablesyou to define the ramping positions for all of the chains one by one.

Confirm the dialog box with thebutton. The length of thenormal can be set in the Normal lengthfield. The distance between the normal andstart of the geometry is set in the Tangentextension field. TangentExtensionNormal Length Thearc radius can be set in the Radius field.

The length of the extension can be set inthe Tangent extension field. The distanceto the material can be set in the Tangentextension field. TangentExtensionLengthWhen the Same as Lead in check box is selected, the strategy andparameters defined for Lead in are used for Lead out.

Under Lead in, choose the Arc optionfrom the list and set the Tangent extensionvalue to 3 and the Radius value to 2. The Pocket operation data is saved and the tool pathis calculated. Add a Drilling operationThis Drilling operation is used to perform thepreliminary center drilling of the four holes inthe corners of the model. The Drilling Operation dialog box is displayed. Define the Drill geometryIn the Geometry area, click thebutton.

This dialog box enables you to select the geometry for drilling directly on the solidmodel. Due to the natureof spline curves or surface boundaries, youcannot pick a center position like you couldon a circle or an arc.

SolidCAM calculates thecenter position of an arc defined by threepoints positioned on the spline edges. Thisfacilitates selecting drill centers on splinesurfaces. Four drill positions are selected. Theircoordinates are displayed in bottompart of the Drill Geometry Selectiondialog box.

Click the button to confirm the geometry selection. The Drilling Operation dialogbox is displayed. Click to start a new drilling tool definition. From theDrilling Tools section, choose the Spot drill tool for theoperation. Spot DrillThis tool type is used for center drilling and chamfering in Drillingoperations. A tool of this type is defined with the parameters shown inthe image. Click the Select button to choose the tool for the operation.

Click the Data tab. Define the spin and the feed for the operation. Define the center drilling depthSwitch to the Levels page of the Drilling Operationdialog box. Click the Drill depth button and selectthe upper face of the model. The Drill depth value 0 appears in the relevant edit box. To perform the drilling down to the specified diameter of the tool, use the Depth typeoption. The Diameter value can vary from 0 all the way up to the drill tooldiameter.

A value greater than the drill tool diameter is automaticallydecreased to the drill tool diameter. Choose the Diameter value option and set the value to 5. In this manner, the drilling is performed till the tooldiameter of 5 mm is reached at the depth of 0. The Drilling operation data is saved and the toolpath is calculated. Simulate the operationSimulate the operation in theSolidVerify simulation mode. Add a Drilling operationAdd another Drilling operation to perform the through drilling of the holes.

Define the GeometryThis operation is using the geometry that was defined inthe previous center drilling operation. Choose the Drillgeometry from the list in the Geometry area. Each geometry defined in SolidCAM has a unique name. When the geometryis being defined, it is assigned a default name that can be changed.

Usingthis name, you can choose the geometry for a specific operation. Click the Data tab in the Tool page. Define the spin and feed for the operation. Define the Drilling depthThe overall height of the model is 10 mmplus the 5 mm bottom offset defined forthe stock.

The drilling has to be performeddeeper than this depth in order to enable thetool to exit from the material and performthe through drilling.

Switch to the Levels page. Define the Upper level by clicking on the top face of the model as shown. Define the Drill depth. Rotate the model and select the bottom face as shown.

Since the Z- offset defined for the stock model is 5mm, set the Delta value to To perform the through drilling, choose the Fulldiameter option in the Depth type area. With thisoption, the drilling is performed until the fulldiameter is reached at the specified drill depth.

This means that the conical part of the tool exitsfrom the material. In this operation, the pecking canned cycle is used for chip breaking. With this cycle, the chip breaking is accomplished by slight retracts of the tool duringthe drilling process. Switch to the Technology page and click the Drill cycle type button. Available drillcycles are displayed. Click the Peck button. The cycle is chosen for the operation. Click the Data button to define the pecking parameters.

The DrillOptions dialog box is displayed. Confirm the data with the OK button. The Drilling operation data is saved, and the tool path is calculated. Simulate the operationSimulate the operation in the SolidVerify simulation mode. Since in the previous operation the drilling diameter was greater than that inthis operation, the drilling results in a chamfer on the drilled holes.

Now you have successfully finished the exercise. The cover is machined on the 3-Axis milling CNC-machine using the machining vice. The part ismachined using two positionings. At the first stage, the workpiece is positioned in the vice as shown below.

At the next stage, the rest of the cover faces are machined using the second positioning. Load the SolidWorks modelLoad the Exercise3. The CAM-Part is defined. Select the CNC-machine controller. Click the arrow in the CNC-Machine section to display the list of post-processors installedon your system. Define the Stock modelIn this exercise, you have to define the Stock model before youdefine the Coordinate System in order to use the workpiece forthe CoordSys definition.

The stock Model dialog box isdisplayed. SolidCAM generates the stock box surrounding the model withthe specified allowances. In the Expand box at section, set thevalue of the Z- parameter direction to 5. This allowance is usedfor the first clamping. Set the value of 2 for the rest of thedirections. Click on the model.

The face is highlighted, and the boxsurrounding the model is displayed. Click the Add box to CAD model button. Confirm the Model dialog box with thedisplayed. The Milling Part Data dialog box is6.

The CoordSys dialog box is displayed. In the Define CoordSys options list, choose the Define option. At first, you have todefine the Coordinate System origin location and then thepoints for the X- and Y-directions.

Pick the origin point in the stock box corner as shown. Click on the stock model edge as shown to define the X-axis of the Coordinate System. Click on the stock model edge as shown to define the Y-axis of the Coordinate System.

When a point is selected, the next button is automatically activated. If youmiss the selection, you can at any time select the button you want to defineand continue automatically to the next button. The model is rotated,The CoordSys Data dialog box is displayed. Define the Part Lower level directly on the solid model. This parameter defines thelower surface level of the part to be milled.

Click the Part Lower level button. Rotate the model and select the lower facethat is milled using the first positioningas shown. The Z-coordinate of the face is displayed in the Pick Part Lowerlevel dialog box. Confirm this dialog box by clicking thebutton.

Confirm the CoordSys Manager dialog box with thedialog box is displayed again. The Milling Part Data7. The target Model dialog box is displayed. This dialog box enables you to define a 3D model for the Target. Press the User Login at the top left corner, in order to enter your User Login data and have full access to all documentation.

For directions and map please visit: Google Maps. Category overview ; List of all discussion forums ; The latest forum topics ; IndustryArena. This video shows, how to generate a CNC machine code using a 3D modeling software Solidworks and also the simulation of machining process on a …. Ray learned that he was getting post processor development and support directly from SolidCAM and not from a third party.

Try it first in the air before you crash your machine. Das Referenzmodell habe ich getauscht. The problem I have come across though is that there doesn’t seem to be a Fanuc mill turn post processor available in Fusion Thank you very much in advance.

SolidCAM provides seamless, single-window integration and full associativity to the SolidWorks design model, essentially putting the most powerful CAM features available right at your fingertips inside SolidWorks. To use post-processor from the list, download the post a.

Use of 3D-CAD data in manufacturing plants is spreading for the purpose of …. A special algorithm prevents the falling of the processed material. Manufacturing Post Processor Utility bit. This post is for the pre-Next Generation Control. Post Library for Autodesk Fusion Coub is YouTube for video loops. Use of 3D-CAD data in manufacturing plants is spreading for …. Re: solidcam simulate 4th axis rotation.

Top posts august 3rd Top posts of august, Top posts Vi vengo a chiedere con gentilezza se qualcuno ha i post …. You can take any video, trim the best part, combine with other videos, add soundtrack. I am also having issues with the motion of the machine , as it ‘s smooth.

So I changed existing – Page 6. To use post-processor from the list,. SolidCAM is used in the mechanical manufacturing, electronics, medical, consumer products, machine design, automotive and aerospace industries, in mold, tool and die and rapid prototyping shops. Just want to give everyone an update on the solidcamx guy. Solved: Mazak M Post Processor. He also really liked that SolidCAM includes all post edits with subscription maintenance.

Thread: All Post Processors. Page 8 of 17 6 7 8 9 10 Jump to page: Results to of Re: All Post Processors. Originally Posted by miramifoto. Hi there! I need a post for an old Biesse Rover 18, to be used in Alphacam Re: All Post Processors hi everybody. Hello, someone have a Post-Prozessor Dmc v iTnc ? Thank you!