Siemens NX CAM Training In Hyderabad
Introduction of Siemens NX CAM
NX CAM helps automate NC programming and reduce cycle times with application-specific, highly effective tools. The NX CAM course will teach you how to use single CAM software from 2.5-axis machining and molding production to systemic 5-axis milling and massive production, allowing you to produce better parts more quickly. After completing this course, you will be able to use NX CAD/CAM and Post Builder to model and device any component and use NX CAM with any CNC machine.
Scope of Course Siemens NX CAM
This programme is designed for people unfamiliar with NX and employees of any company who understood NX a long time ago and need a quick refresher on the tools and operations they can immediately apply to their projects. After completing this course, you will be able to
Generate G code for operations such as Multi-Axis Milling, Planar, Contour, Hole Making, Turning, and Wire EDM.
Understand the CAM concept and the most frequently used operations of Siemens NX by operating individually on any version of any part.
Generate workpieces for any complicated part using the NX CAM operations illustrated in Examples and Exercises.
They create toolpaths and CNC programming for them.
Career Prospects / Job Roles after Siemens NX CAM
NX CAM is the most widely used manufacturing software across all industries, from aviation to energy. Anyone with an understanding of NX CAM can quickly find employment because:
Machine Operator / Machinist
CAD Engineers and Designers
and Manufacturing Engineers
Syllabus for Siemens NX CAM Courses in Hyderabad
Session - 1
INTRODUCTION TO MANUFACTURING & NX-CAM
Introduction to manufacturing
About manufacturing types
About machining types
Milling operations overview
Introduction to CAM
Benefits of CAM
Introduction to NX CAM
Benefits of NX CAM
About Conventional milling and Climb milling
Milling machines overview
Milling cutters overview
Manufacturing in NX
Understanding CAM terminologies
Understanding CAM set up
About CAM configuration
About NC assistant
About Milling processors and operation sub types
Session - 2
Operation Navigator overview, Operation status symbols
Editing Operations, Transform Operations
Geometry Groups overview, MCS overview
In Process Work piece, Assigning material to part
About milling tool types, About tool holder
Retrieving Tools from Tool Library
Program and Method Groups:
About Program groups, About Method group creation
Defining Feed rates
Visualize and Analyze:
Understanding Tool Path Visualization, Understanding Visualization Replay
Understanding Dynamic Visualization, Understanding IPW thickness by color
About Gouge Checking, About Generating Tool Paths
Parallel Generate overview, Verify Tool Path overview
About Installation of Postprocessor, Generating program using Post process
Generating Shop Documentation
Session - 3
MILLING OPERATION - I
Facing Milling Operation:
Introduction to Face Milling operation, Specifying Check bodies
Specifying face boundaries, Defining Path Settings, Defining Stopover
Defining Cut Patterns
Creating Face Milling Area Operation, Defining Cut Walls
Defining Mixed and Manual Cut, Patterns
Post process a program, Generating Shop Documentation
Planar Milling Operation:
Introduction to Planar milling operation
Specifying part geometries, Stock overview
Defining Non cutting moves, Defining Transfer/Rapid
Session - 4
MILLING OPERATION - II
Planar Profile Operation
Creating Planar Profile Operation
Planar Milling Operation
Planar Operation using Standard Drive cut pattern
Planar Text Operation
Creating Planar Text Operation
Thread Milling Operation
Creating Thread Milling Operation on Hole and Boss feature
Contour Milling Operation
Creating Cavity Milling Operation
Defining Wave Geometry Linker
Defining Trochoidal cut pattern
Machining based on level based IPW
Session - 5
MILLING OPERATION - III
Rest Milling Operation
Creating Rest Milling Operation
Defining Cut levels
Z-level Milling Operation
Creating Z Level Milling Operation
Defining Containment for blank
Creating Additional Passes
Defining Step over in Path Settings
Surface Contouring Operation
Creating Contour Area Non Steep Operation
Milling Operation based on Area Drive method
Creating Contour Area Operation
Defining Cut Direction
Editing Tool display
Defining Trim Boundary
Specifying Cut Angles
Specifying Directional Steep
Session - 6
RADIAL CUT OPERATION
Creating Fixed Contour Operation
Defining Radial Drive method
Editing Band Parameter
Engraving Text on Contour Surface
Creating Contour Text Operation
Session - 7
VARIABLE CONTOUR OPERATION
Creating Variable Contour Operation
Defining Normal to Drive method
Creating Variable Contour Operation using Normal to Part Tool Axis method
Defining Projection Vector and Tool Axis
Defining Lead Angle
Creating Variable Contour Operation using Interpolated Tool Axis vectors
Interpolating Tool Axis
Session - 8
MULTI BLADE MILLING OPERATION
About Turbo machinery Milling Operation
Creating Multi Blade Roughing Operation
Specifying Hub geometry
Specifying Shroud geometry
Specifying Blade geometry
Specifying Blend geometry
Defining Drive Methods
Defining Cut Levels
Creating Multi Blade Hub Finish Operation
Creating Multi Blade Finish Operation
Session - 9
About Drilling machines
About Drilling tools
About Drilling tool material
Various Drilling operations
Operation sub types in Drilling Operation
Defining Drill geometry
Creating Spot Drilling Operation
Creating Drilling Operation
Creating Counter Boring Operation
Creating Reaming Operation
Creating Peck Drilling Operation
Creating Boring Operation
Creating Counter Sinking Operation
Session - 10
About Lathe machines
Various tools available for Turning Operation
Operation subtypes in Turning Operation
About Part geometry
About Blank geometry
About Cut Region Containment
Defining Turning Work piece
Defining Trim Planes
Create Roughing and Facing Operation
Create Grooving and Boring operation
IPW definition in 2D and 3D
Create Spot and Peck Drilling Operation
Turning Operation using multiple spindles
Creating Teach Mode Operation
Creating Thread cutting in Turning Operation
FAQs on Siemens NX CAM
What is NX CAM?
NX CAM is a computer-aided manufacturing (CAM) software solution from Siemens that enables users to quickly and accurately program complex parts. It offers a range of powerful CAD modeling and machining capabilities, and is designed to help users get their parts to market faster.
What are the benefits of using NX CAM?
NX CAM provides users with a range of powerful CAD modeling and machining capabilities, including 3D CAD modeling, NC programming, multi-axis machining, and more. It is designed to help users get their parts to market faster, and is easy to learn and use.
Does NX CAM offer 3D CAD modeling capabilities?
Yes, NX CAM offers powerful 3D CAD modeling capabilities, including solid modeling, surface modeling, and freeform modeling. It also offers NC programming and multi-axis machining capabilities.
What type of parts can be programmed with NX CAM?
NX CAM can be used to program a variety of parts, including complex shapes, molds, castings, and more. It is designed to be easy to learn and use, so even users with limited experience can quickly and effectively program parts. NX CAM also supports a wide range of materials and technologies, including milling, turning, grinding, and EDM (electrical discharge machining).
What are the benefits of NX CAM?
NX CAM offers a number of benefits to users, including improved productivity, reliable and accurate results, and improved product quality. It also provides a wide range of options for users to customize the programming process to their specific needs, such as customizing tool paths, setting feed rates, and adjusting cutting parameters.
Does NX CAM support 3D machining?
Yes, NX CAM supports 3D machining, including 3+2 axis machining, 5-axis contouring, and 5-axis simultaneous machining.
What CAD software is compatible with NX CAM?
NX CAM is compatible with a number of CAD software packages, including Catia, Pro/ENGINEER, SolidWorks, Autodesk Inventor, and more. It also supports popular file formats such as DWG, DXF, STEP, and IGES.
Does NX CAM support automated programming?
Yes, NX CAM has a variety of tools for automated programming, such as NC Code generation, intelligent tool selection, collision detection, and automated toolpath optimization.
What type of manufacturing processes can be programmed in NX CAM?
NX CAM supports a variety of manufacturing processes such as milling, turning, drilling, tapping, boring, reaming, and many others. It also provides advanced feature-based machining, high-speed machining, and multi-axis machining capabilities.
Does NX CAM support simulation and verification?
Yes, NX CAM includes integrated simulation and verification capabilities, which allow users to test and validate the accuracy and reliability of their NC programs. Additionally, NX CAM also offers advanced simulation features such as collision detection, cut-time analysis, and toolpath optimization.