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Projections and Views

A three-dimensional object can be repre­sented in a single plane, such as on a sheet of paper, using projecting lines and planes. All projection theory is based on two variables: line of sight (projecting lines) and plane of projection.

A line of sight (LOS) is an imaginary line between an observer’s eye and an object. A plane of projection (i.e., an image or picture plane) is an imaginary flat plane upon which the image is projected. The projection is produced by connecting the points where the lines of sight pierce the projection plane. As a result, the 3D object is transformed into a 2D view.

If the distance from the observer to the object is infinite, then the projection lines are assumed to be parallel, and the projection is called a parallel projection. Parallel projection is orthographic if the plane of projection is placed between the observer and the object, and the plane is perpendicular to the parallel lines of sight.

Orthographic projection

You can use parallel projection technique to create both multiview and pictorial (isometric and oblique) views.

multiview and pictorial (isometric and oblique) views

  1. In multiview orthographic projection (see details below), the object surface and the projection plane are parallel, and you can see only two dimensions.
  2. In isometric view (orthographic) the surface is no longer parallel to the projection plane, but the latter is perpendicular to the lines of sight, with three dimensions being seen.
  3. In oblique projection (non-orthographic) the object surface and the projection plane are also parallel, but the lines of sights are not perpendicular to the projection plane, and you can see again three dimensions.

If the distance from the observer to the object is finite, then the projection lines are not parallel (since all lines of sight start at a single point), and the drawing is classified as a perspective projection. In perspective view the object surface and projection plane can be also parallel.

perspective projection

Multiview projection

By changing position of the object relative to the line of sight you can create different views of the same object. Drawing more than one face of an object by rotating the object relative to your line of sight helps in understanding the 3D form. Having several views on one drawing you use the concept of multi-view projection, which is based on the orthographic (parallel) projection technique where

  • the plane of projection is positioned between the observer and the object,
  • the plane of projection is perpendicular to the parallel lines of sight, and
  • the object is oriented such that only two of its dimensions are shown.

Main principles of creating multiview projections

The plane of projection can be oriented to produce an infinite number of views of an object. However, the most common views are the six mutually perpendicular views that are produced by six mutually perpendicular planes of projection:

  • Front view – the one that shows most features or characteristics.
  • Left side view – shows what becomes the left side of the object after establishing the front view position.
  • Right side view – shows what becomes the right side of the object after establishing the front view position.
  • Top view – shows what becomes the top of the object once the position of the front view is established.
  • Bottom view – shows what becomes the bottom of the object once the position of the front view is established.
  • Rear view – shows what becomes the rear of the object once the position of the front view is established.

The most informative (descriptive) view of the object to be represented is normally chosen as the principal view (front view). This is view A related to the corresponding direction of viewing A and it usually shows the object in the functioning, manufacturing, or mounting position.

multiview projections
View positions on drawings and corresponding viewing directions

Positions of the other views relative to the principal view in the drawing depend on the projection method.

The number of views and sections must be limited to the minimum necessary to fully represent the object without ambiguity.

Unnecessary repetition of details must be avoided.

Conventional view placement

Generally, three views of an object are enough, however, a drawing must contain as many views as necessary to illustrate the part, usually at right angles to one another.

Frontal plane of projection

In multiview projection, the object is viewed perpendicular to the main faces, so that only one face of the object is depicted in each view. The frontal plane of projection is the plane onto which the front view of a multiview drawing is projected.

frontal plane of projection

In the front view you can see height and width of the object, but you cannot see its depth.

front view

Horizontal plane of projection

The top view is projected onto the horizontal plane of projection, which is plane suspended above and parallel to the top of the object.

Horizontal plane of projection

The top view of an object shows the width and depth dimensions.

top view

Profile plane of projection

In multiview drawings, the right side view is the standard side view. The right side view is projected onto the right profile plane of projection, which is a plane that is parallel to the right side of the object. However, you can also use the left side view if it is more descriptive and informative. Moreover, when needed, you can include both side views into one drawing.

Profile plane of projection

The side view of an object shows the depth and height dimensions.

side view

The three-view multiview drawing is the standard used in engineering and technology, because often the other three common views are mirror images and do not add to the knowledge about the object.

The standard views used in a three-view drawing are the

  • top,
  • front, and
  • right side views,

arranged as shown in the figure:

three-view drawing

The width dimension is common to the front and top views. The height dimension is common to the front and side views. The depth dimension is common to the top and side views.

For simple parts one or two view drawings will often be enough. In one-view drawings the third dimension may be expressed by a note, or by descriptive words, symbols, or abbreviations, such as Ø, HEX, etc.

Dimensioning of a bolt

Square sections may be indicated by light crossed diagonal lines, as shown above, which applies whether the face is parallel or inclined to the drawing plane.

Another example of a one-view drawing:

One-view drawing

Additional views may be added if they improve visualization.

The views should also be chosen to avoid hidden feature lines whenever possible. That means that the most descriptive view should be shown.

1st & 3rd angle projections

Besides, you should select the minimum number of views needed to completely describe an object. Eliminate views that are mirror images of other views.

Redundant view

Why multiview drawings technique is so important?

To produce a new product, it is necessary to know its true dimensions, and true dimensions are not adequately represented in most pictorial drawings. For example, the photograph is a pictorial perspective image. However, as you can see, the image distorts true distances, while the latter are essential for manufacturing and construction, and in this example the case in question is the width of the road, not the electrical pole!

image distorts true distances

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In mechanical engineering perspective projections distort measurements.

As you can see, the two width dimensions in the front view of the block appear different in length in the perspective projection. In other words, equal distances do not appear equal on a perspective drawing.

equal distances do not appear equal on a perspective drawing

Thus, since engineering and technology depend on exact size and shape descriptions for design, the best approach is to use the parallel projection technique (orthographic projection) to create multi-view drawings where each view shows only two of the three dimensions (width, height, depth).

To summarize:

The advantage of multiview drawings over pictorial drawings is that multiview drawings shows the true size and shape of the various features of the object, whereas pictorials distort true dimensions which are critical in manufacturing and construction.

1st & 3rd angles (glass box)

What exactly you should place on the right side projection?

Is it that we can see from the left side, or from the right side of the object?

To answer these questions there are two different ways, based on two different principles

  • First-Angle Projection
  • Third-Angle Projection.

Third angle is used in Canada and the United States. First angle is used in Europe.

In third angle orthographic projection the object may be assumed to be enclosed in a glass box.

Third-Angle Projection

Each view represents that which is seen when looking perpendicularly at each face of the box.

open box

The resulted views are identified by the names as shown.

Third-Angle views

The front, rear, and side views are sometimes called elevations, e.g., front elevation. The top view may be termed the plan.

If desired, the rear view may be shown both ways – at the extreme left or the extreme right. When this is not practical to show rear view at he extreme left or right due to the length of the part, particularly with panels and mounting plates, the rear view should not be projected up or down, as this would result in its being shown upside down.

Instead, it should be drawn as if projected sideways, but located in some other position, and should be clearly labelled REAR VIEW REMOVED.

Rear View Removed

In first angle orthographic projections the object is considered as being rolled over to either side, so that the right side of the object is drawn to the left of the front elevation:

1st angle projection

It is mandatory to indicate the method of multiview projection by including the appropriate ISO (International Organization for Standardization) projection symbol – the truncated cone:

truncated cone

You should place this symbol in the lower right-hand corner of the drawing in or adjacent to the title block.

Axonometric projection

It is one of the pictorial drawing pro­jections, which are useful for illustrative purposes, educational aids, installation and maintenance drawings, design sketches, and the like.

The Greek word axon means axis and metric means to measure. Axonometric projection is a parallel projection technique used to create a pictorial drawing of an object by rotating the object on an axis relative to a plane of projection.

Axonometric projection

Axonometric projections such as isometric, dimetric, and trimetric projections are ortho­graphic, in that the projection lines are all parallel, but the angle of views is so chosen that three faces of a rectangular object would be shown in a single view.

Axonometric drawings are classified by the angles between the lines comprising the axonometric axes. The axonometric axes are axes that meet to form the corner of the object that is nearest to the observer.

Axonometric views

When all three angles are unequal the drawing is classified as a trimetric. When two of the three angles are equal the drawing is classified as a dimetric. When all three angles are equal the drawing is classified as a isometric.

Although there are an infinite number of positions that can be used to create such a drawing only few of them are used.

Enlarged detail

To eliminate the crowding of details or dimensions, an enlarged removed view may be used.

ÌýDetail example - 1Detail example - 2

  • The enlarged view should be oriented in the same manner as the main view,
  • the scale of enlargement must be shown, and
  • both views should be identified by one of the methods shown in the illustrations – with the leader line or with the circle line. The circle enclosing the area on the main view should be drawn with a thin line.
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