Lecture 5: Curves And Surfaces, and Geometric Modeling PREPARED BY: NOR HELYA IMAN BT KAMALUDIN PTT105: Engineering Graphics
INTRODUCTION ABOUT GEOMETRIC MODELING… CAD tools have been defined as the melting pot of three disciplines: design, geometric modeling, and computer graphic. A geometric model should be unique and complete to all engineering functions, from documentation to engineering analysis to manufacturing. PTT105: Engineering Graphics
PTT105: Engineering Graphics CURVES Geometric description of curves defining an object can be tackled in several ways. A curve can be described by arrays of coordinate data or by an analytic equation. Majority of the curves were circles, but some were free-form. Those are curves arising from applications such as ship hull design to architecture. PTT105: Engineering Graphics
PTT105: Engineering Graphics When they had to be drawn exactly, the most common tool was a set of templates known as French curves. French curve: carefully designed wooden curves consist of pieces of conics and spirals. A conic section is a curve obtained by intersecting a cone with a plane. 3 types of conic section are ellipse, parabola, hyperbola. PTT105: Engineering Graphics
PTT105: Engineering Graphics 1. Ellipse An ellipse is a smooth closed curve which is symmetric about its horizontal and vertical axes. In geometry, an ellipse is results from the intersection of a cone by a plane in a way that produces a closed curve. Circles are special cases of ellipses, obtained when the cutting plane is orthogonal to the cone's axis. An ellipse is also the locus of all points of the plane whose distances to two fixed points add to the same constant. PTT105: Engineering Graphics
PTT105: Engineering Graphics Example of an ellipse: PTT105: Engineering Graphics
PTT105: Engineering Graphics 2. Parabola Parabola is a conic section, the intersection of a right circular conical surface and a plane parallel to a generating straight line of that surface. For parabola, the locus of points are equidistant from a given point (the focus) and a corresponding line (the directrix) on the plane. The parabola has many important applications such as in designing automobile headlight reflectors and ballistic missiles. PTT105: Engineering Graphics
PTT105: Engineering Graphics Example of a parabola: PTT105: Engineering Graphics
PTT105: Engineering Graphics 3. Hyperbola The hyperbola is one of the three kinds of conic section, formed by the intersection of a plane and a cone. A hyperbola is an open curve with two branches, the intersection of a plane with both halves of a double cone. The two pieces of branches formed mirror images of each other and resembling two infinite bows. PTT105: Engineering Graphics
Example of a hyperbola: PTT105: Engineering Graphics
PTT105: Engineering Graphics SPLINES Another mechanical tool of curve, called a spline was also used. Spline is a flexible strip of wood that are held in place and shape by metal weights, known as ducks. A spline “tries" to bend as little as possible, resulting in shapes which are both aesthetically pleasing and physically optimal. PTT105: Engineering Graphics
PTT105: Engineering Graphics Spline Curve Description: Spline curve is one of the most fundamental parametric curve forms. It is a mathematical counterpart to a mechanical spline. Features: Curve that can minimize certain functionality Act as piecewise polynomial (or rational polynomial) curves with certain smoothness properties. PTT105: Engineering Graphics
PTT105: Engineering Graphics Example of Splines PTT105: Engineering Graphics
PTT105: Engineering Graphics SURFACES Surface models have an infinitely thin computer- calculated surface between their edges. Although they appear to be solid, they are an empty shell. The model on the left in the figure shows the previous object as a surface model. PTT105: Engineering Graphics
PTT105: Engineering Graphics They appear to be a round hole through the model. The hole is actually a tube simulating the surface of a hole, as can be seen in the center model, in which a surface panel has been removed. Surface model often use wireframe models as a frame for their surfaces. PTT105: Engineering Graphics
PTT105: Engineering Graphics Rectangular Surfaces Rectangular surfaces are a map of a rectangular domain into 3D parametric surface. Mapping the rectangular domain to a 2D parametric surface, resulting in a distortion of that rectangle. For example, if we embed a curve in this domain rectangle, we will obtain a deformed curve. PTT105: Engineering Graphics
Application of rectangular surfaces PTT105: Engineering Graphics
SOLID GEOMETRIC MODELING • Solid models have both edge and surfaces, plus computer-calculated mass under their surfaces. Solid models provides mass property information: volume, center of gravity, mass moment of inertia. • The example of solid model is shown below. PTT105: Engineering Graphics
PTT105: Engineering Graphics It appears very similar to a surface model But, if we sliced in in half, as demonstrated in the center model, it show truly solid. Basic rule for solid modeling – all surfaces must touch another surface PTT105: Engineering Graphics
Example of Solid Modeling PTT105: Engineering Graphics
PTT105: Engineering Graphics Solid Modeling • 3 different types of solid modeling: – Primitive modeling – Constructive solid geometry (CSG) – Feature-based modeling (FBM) PTT105: Engineering Graphics
PTT105: Engineering Graphics 1. Primitive Modeling • Objects described using basic geometrical forms. • Common geometric primitives. PTT105: Engineering Graphics
PTT105: Engineering Graphics Example: PTT105: Engineering Graphics
2.Constructive Solid Geometry (CSG) • More flexible and powerful than primitive. • Allow Boolean Operations: - union, difference & intersection PTT105: Engineering Graphics
PTT105: Engineering Graphics Boolean operation PTT105: Engineering Graphics
PTT105: Engineering Graphics Example using CSG: PTT105: Engineering Graphics
PTT105: Engineering Graphics Example using CSG: PTT105: Engineering Graphics
3. Feature-based Modelling (FBM) • 3D model is built using series of features, such as hole, slot, square block, etc. • Each feature can be independent or linked to other feature. • The geometry of each feature is controlled by modifiable constraints and dimensions. PTT105: Engineering Graphics
PTT105: Engineering Graphics FBM: 3D operations Basic concept – 2D cross-section or profile is produced – Depth is given to the profile • Generally 4 types** – Extrude – Revolve – Sweep – Blend **different terms might be used in different software/books PTT105: Engineering Graphics
PTT105: Engineering Graphics 1. 3D Ops: Extrude A linear sweep, where the profile is given a depth in straight line, perpendicular to the profile plane PTT105: Engineering Graphics
PTT105: Engineering Graphics 2. 3D Ops: Revolve The profile is rotated around a defined axis, 0 – 360 degree PTT105: Engineering Graphics
PTT105: Engineering Graphics 3. 3D Ops: Sweep The new command and is similar to the EXTRUDE command, but it concentrates on using paths to define the direction of the extrusion. This command SWEEP a 2D object along a path. PTT105: Engineering Graphics
PTT105: Engineering Graphics 3D Ops: Sweep & Blend PTT105: Engineering Graphics
Steps in building 3D object PTT105: Engineering Graphics
Examples of FBM + Boolean PTT105: Engineering Graphics
PTT 105/3: Engineering Graphics