Siemens NX Mastery : 500 Examples|20 Project|300 Q&A|10 Test

Compare NX 2306 and NX 11 sketcher interfaces, highlighting tool differences, relaxing constraints, and switching between newer and older sketcher modes using early access settings.

Learn to constrain a rectangle with geometrical and internal constraints, create a sketch, apply coincident, vertical, horizontal, perpendicular, and parallel relations, and dimension to 100 by 250 units.

Open a new sketch in Siemens NX, create a simple profile, and apply geometric constraints (horizontal, vertical, equal) and dimensioning to generate a fully constrained drawing.

Learn to create and constrain a circle in the Siemens NX sketcher, defining center coordinates, radius or diameter, and applying dimensions to manage degrees of freedom.

Learn to create a fully constrained sketch in nx by drawing a rectangle with four lines, then add circles with center points, diameter, equal radius, and horizontal alignment constraints.

Learn to create jumpers in Siemens NX by sketching lines and a rectangle, using the jumper tool in symmetric, distance-based, or angle-based modes to generate fully constrained geometry.

Open a new NX sketch, set the base, and enforce symmetry along the y-axis with constraints. Dimension, trim, and add circles and symmetric jumpers to create a fully constrained design.

Master the centered-drawing workflow in Siemens NX Mastery by constructing concentric circles, applying constraints, and dimensioning lines to achieve fully constrained geometry in example-13.

Learn to create a circle by three points and to generate a polygon with a chosen number of sides, exploring inscribed and circumscribed options, rotation, and fully constrained geometry.

Learn to use Pattakos Patternmaker to duplicate existing curves into predefined linear and circular patterns, control item count and spacing, and edit pattern variables.

Utilize the offset tool to create parallel curves at a set distance and reverse direction. Then construct conics from three points—start, a point, and a control point—producing parabola or hyperbola.

Practice example 15 by constructing center and peripheral circles and lines, rotating six equally spaced elements around the center, and setting radii and diameters to reach a fully constrained sketch.

Explore the part navigator window to access the history of created parts and sketches, and review the sequential model history by opening the example 20 file.

Learn to apply a chamfer to solid edges using the jumper tool, select edges, and control distance, angle, or offset, including symmetric jumper applications on multiple edges.

Practice building the example 27 model by sketching a symmetric base with circles and lines, applying automated constraints, finishing the sketch, then extruding and adding holes to complete the part.

Explore primitives in Siemens NX by creating blocks, cylinders, cones, and spheres from defined origins and points, then edit dimensions, apply extrusions, and perform boolean operations.

Create a new NX file, sketch concentric circles with precise diameters, revolved to form the main body, then unite two solids to generate the final 3D object.

Mirror geometry mirrors entire bodies across a plane; mirror feature copies a specific feature on a single body, requiring uniting bodies for multi-body work.

Create datum planes in Siemens NX using the Tamplin option with distance and angle from a reference plane, aligning with the global coordinate system X-axis and Y-axis.

Create a complete Siemens NX example 32 by sketching a profile, constraining dimensions, extruding to form a 3D model, then adding fillets, holes, slots, duplication, mirroring, and an isometric view.

Learn to sweep a cross section along a guide in Siemens NX, using sketches and a circular profile to generate pipes, with first and second offsets shaping the route.

Apply draft to solid faces in Siemens NX by selecting a direction and edge, then set an angle relative to the axis to generate a draft on multiple edges.

Learn to create cylindrical and rectangular pockets on a face, specify diameter, depth, and angle, and precisely position features using perpendicular distances and centerline references.

Create grooves on cylindrical faces by using rectangular group, centerline references, and precise dimensions, adjusting translucency to reveal centerlines and executing groove variations directly on the solid.

Begin by wireframing directly in three-dimensional space, using three-point circles and line tools to build a sketch without planes, then refine with arcs and dimensional constraints.

Create lines with axis locking to x, y, and z and build a 15 by 100 rectangle; explore associative versus non-associated lines and how deletions affect related geometry.

Create inscribed and circumscribed polygons in Siemens NX Mastery by adjusting radius, center, and orientation to achieve precise sides and angles.

Insert text in a Siemens NX model using the Cut ribbon, place it on edges or faces, and adjust alignment, anchor, offset, and font style to create embossing effects.

Learn to create surfaces in Siemens NX using four point surface, bounded plane, and sheet from curves, with step-by-step selections and comparison of options.

Create a surface from a sketch and extrude to form a box, then trim or split the body along the surface to remove a portion or create two bodies.

Create example 18's complete surface model by sketching a symmetric rectangle base, extruding, trimming, and sewing multiple surfaces into a single surface with no intersections.

Create surfaces using ruled surfaces and through curves, define reference curves, and generate surfaces between open or closed sketches in NX with practical steps.

Learn to create a surface by sweeping a section along a guide in NX, using sketches, planes, and preferences to generate a smooth surface.

Create a swept surface using a script tool, connecting up to three guides with cross sections and sketches, and orient the surface along the guides while adjusting direction for consistency.

Use patch opening to fill holes and defects on surfaces by selecting the surface and edge, creating a patched surface and simplifying surface modeling.

Create a single folder for all parts related to the main valve assembly, then develop independent models and insert them into the main assembly file to build the valve assembly.

Create a bolt in Siemens NX using primitives: model a 20 by 45 mm body and 30 by 10 mm head, form a hexagon recess, and save to assembly folder.

Siemens NX Mastery demonstrates generating a 3d model of Dyball, starting from a constrained sketch on the xy plane, extruding shapes, and adding a symbolic thread on a surface.

Create an assembly file that links all Volvo assembly components stored in a single folder, ensuring every part is present so the assembly opens correctly.

Master valve assembly in Siemens NX by importing the plate, aligning axes with touchline constraints, and fixing rotation and translation to create a fully constrained assembly.

Assemble the cover into the main assembly using the three tables, align axes to control rotation and translation, and apply a distance constraint between bottom and top faces.

Position components, apply parallel and perpendicular constraints, and fix remaining degrees of freedom in NX, then create a circular pattern to complete the valve assembly.

Learn to change colors and apply translucency to Siemens NX models to clearly identify individual parts, selecting objects and applying colors for a glass-like visibility.

Orchestrate the final drone assembly by reading the bill of materials, recognizing parts like main frame, arm, propeller, and controller, and assembling them with proper constraints.

Begin the aircraft landing gear assembly final project using the provided drawings and bill of materials, then create and constrain assembly with cylinder, piston, arms, pins, bolts, and wheel assembly.

Create a detail view from a two-times scaled area to show dimensions of complex geometry, using circle and rectangle examples in the drafting interface.

Learn to create cross hatch for sectional views and apply area fill in nx, using region selection tools and adjustable patterns to shade surfaces.

Insert and customize tables in drawings to manage repetitive dimensions, adjusting columns, rows, and column width, then edit text and fonts and attach a leader line.

Add new drawing sheets in the drafting module by inserting sheets, configuring the standard dialog for size and parameters, and placing base and isometric views for print output.

Explore blade design and air flow in a gas turbine, covering compressor and turbine blades, guide vanes, and impellers, with five projects modeling aerofoils from real drawings.

Explore aerofoils, their low-drag advantage, and their role in blade design for gas turbines; learn aerofoil geometry and its application across aircraft and turbine blades.

We create the section 2-2 aerofoil profiles, concave and convex, by importing coordinates from Excel, saving as dat files, and generating splines from the data.

Generate the section three aerofoil profile by importing concave and convex data and saving them as dat files, then build splines from file points for the leading and trailing edges.

Import concave and convex data from Excel to create the fourth aerofoil section, save it as a dat file, and build four profiles with tangent and point on curve constraints.

Create an axial dovetail route by forming a half cross section, mirroring for symmetry, extruding to a blade root, and cutting with a 25-degree rotated plane.

Apply finishing touches to the fifth-stage compressor rotor blade model: add transition radius R3 with edge blend, then trim blade height from 95 mm to 90 mm.

Import concave and convex aerofoil coordinates from Excel into section data dat files, then use the spline tool to form the second aerofoil section II-II with tangency and constraints.

Forge section three aerofoil profiles in Siemens NX Mastery by importing concave and convex data from Excel, creating spline curves from points, and defining leading and trailing edges with constrained sketches.

Import concave and convex aerofoil data from Excel, create splines and arcs, apply tangency and other constraints to fully constrain four profile sketches at different heights, preparing the fifth section.

Import concave and convex cross-section data from Excel to create the fifth aerofoil section, generate the curve with a spline, and assemble five sections into the blade body.

Revolve the cross section about the engine axis to create the radial route solid, then cut ten degrees on both sides using mirrored sketches and extrude operations.

Import coordinate data into Siemens NX, create a plane, and sketch a closed aerofoil section with leading and trailing edge arcs, applying point-on-curve and tangency constraints and radii from data.

Sketch aerofoil section II-II by defining leading and trailing edges with arc and spline, apply constraints and radii 1.9 and 0.5, and finish the closed sketch to form a solid.

Sketch five aerofoil cross sections with datum planes, points on curves, and tangency, then set leading and trailing radii, constrain fully, and build the closed aerofoil profile.

Create the next cooling channel section in Siemens NX by offsetting the aerofoil curve 1.5 mm and defining a 1 mm leading, 0.6 mm trailing radius to form section UU.

Sketch and dimension the section TT cooling channel profile, apply offsets, radii, and tangency constraints, then build through curves and unite/subtract to reveal internal cooling channels.

Design an aircraft turbo starter impeller by interpreting the given drawing, generating four aerofoils from section data, and assembling the blade into the complete body.

Prepare aerofoil data for importing into dimension X by transferring coordinates from the Excel sheet to notepad, saving four section files, and converting them to dat format for Siemens software.

Import aerofoil cross sections into Siemens NX by creating new file and using the spline tool with points from file, then rotate dynamic UCS to stack along the y axis.

Create the keyway slot by sketching a six millimeter wide rectangle on the top plane, positioned 12.5 mm from the impeller axis, then extrude through all.