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CE En 112 Engineering Drawing with CAD Application. Chapter 2: Sketching and Text (Lecture B) Multiview Drawings. Lecture Outline. Objectives Projection methods (2.4, p.85) Multiview projections (2.4.4, p.93) Multiview sketches (2.6, p.99) Visualization (in the PP file only)
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CE En 112 Engineering Drawing with CAD Application Chapter 2: Sketching and Text (Lecture B) Multiview Drawings
Lecture Outline • Objectives • Projection methods (2.4, p.85) • Multiview projections (2.4.4, p.93) • Multiview sketches (2.6, p.99) • Visualization (in the PP file only) • Multiview representations (in the PP file only) • ANSI standards (in the PP file only) • Next class
Objectives • Learn the rules for reducing a 3D object onto a 2D multiview drawing • Learn some hints for visualizing a 3D object from a 2D multiview drawing • Covers material in Chapter 2, primarily Sections 2.4, 2.5, and 2.6 as well asmaterial not in text
Projection Methods (2.4) Locate multiview projections in the taxonomy of projections: Projection Parallel Projections Orthographic Projections Multiview Projections
Object Projection plane Line of sight Multiview Projections (2.4.4) Multiview is classified as parallel projection because lines of sight used to view the object are parallel
Multiview Projections (con’t) Multiview projection is an orthographic projection for which the object is behind the plane of projection and oriented such that only two of its dimensions are shown
Multiview Projections (con’t) Object suspended in a glass box, producing the six principal views Six Principal ViewsSee also Figure 2.35 in text
Multiview Projections (con’t) • Glass box video: • http://highered.mcgraw-hill.com/sites/0072864583/student_view0/chapter5/animations.html#
US (ANSI 3rd-angle projection) vs. ISO (1st-angle projection) Multiview Projections (con’t)
Multiview Projections (con’t) • Choosing the views and orientation for a multiview object: • Determine the best position of the object • Try to make the surfaces of major features either perpendicular or parallel to the projection planes • Define the front view (the front view should show the object in its natural or assembled state) • Determine the minimum number of views needed to completely describe the object so it can be produced • Once the front view is selected, determine which other views will have the fewest number of hidden lines
Multiview Projections (con’t) View Orientation Bad orientation Good orientation
Multiview Projections (con’t) Most Descriptive Views (More visible lines better)
Multiview Sketches (2.6) • Multiview drawings can have from one to three or more views of an object (rarely are more than three views necessary) • One-view sketches: include simple objects such as a sphere, cylinder, or cube. Other applications include a thin gasket or printed circuit board (no depth) • Two-view sketches: include cylindrical, conical, and pyramidal shapes • Three-view sketches: used when an object is more complex and requires three views to communicate all aspects of the drawing (width, depth, and height)
Multiview Sketches (con’t) One-View Sketches Two-View Sketches
Creating a Three-view sketch: Step 1: Block in the front, top, and right side views. Sketch the front view first using construction lines to project dimensions Step 2: Lightly block the major features in views Step 3: Use construction lines to project the location and size of features between views Step 4: Finish adding the final lines Multiview Sketches (con’t)
Normal plane Oblique plane Inclined plane Visualization of Edges and Planes Fundamental Views of Planes
Oblique line Normal line (true-length) Inclined line Visualization (con’t) Fundamental Views of Edges
Visualization (con’t) Normal, Inclined, or Oblique? A: parallel to frontal plane B: parallel to horizontal plane C: parallel to profile plane D: inclined – on edge in front view E: oblique – neither parallel or on edge in any plan or view
Multiview Representations • Practice makes perfect, without it, you will never learn this art of visualizing 3D objects from 2D multiview drawings • Some items to consider in multiview representation and visualization: • Projection studies • Physical model construction • Adjacent labeling • Missing lines • Vertex labeling • Analysis of solids • Analysis of surfaces
Multiview Representations (con’t) Adjacent Areas Possible Solutions
Multiview Representations (con’t) There are several examples of multiview representations in this and other texts. The best method to learn the art of multiview representation of 3D objects is to draw by yourself, with tools or freehand, the objects in the Problems section of the text. We do not have time to cover all that are presented in the chapter. This section presents some examples of multiview representation.
Multiview Representations (con’t) This length has to be measured. And the curved line in top view must be drawn first. (The bottom plane is flat.)
ANSI Standards for Multiview Drawings Partial Profile Views to Describe an Object and Eliminate Hidden Lines Partial View used on a Symmetrical Object
ANSI Standards (con’t) Too “busy” Revolution Conventions used to Simplify the Representation of Ribs and Webs
ANSI Standards (con’t) Removed View Make the drawings easy to understand! Revolution Applications
Examples Use overhead slides
Next Class • Dimensioning