1. Introduction
In the course of engineering drawing, it is often necessary to make a certain
geometrical constructions in order to complete an outline.
There are no projections involved, and no dimensioning problems, the ONLY
GREAT DIFFICULTY IS ACCURACY.
Common geometric shapes
2. PRELIMINARY TECHNIQUES
Geometrical Construction Techniques
LINES
A POINT has no area,
it indicates a position,
it can be indicated by a
dot or thus
A LINE has length but
no area. It may be
curved or straight.
A STRAIGHT LINE is
the shortest distance
between two points.
GEOMETRICAL TERMS
3. BISECTING/PERPENDICULARS/PARALLELS/DIVISION
1) BISECT A LINE
1. With a compass opened to a
distance greater than half AB, strike
arcs from A and B.
2. A line joining the points of
intersection of the arcs is the
bisector.
2) BISECT AN ACUTE ANGLE
1. Set an acute angle (angle less than
90:), and bisect the angle.
3) BISECT OF A GIVEN ARC
1. With centre A and radius greater
than half AB, describe an arc.
2. Repeat with the same radius from B,
the arcs intersecting at C and D. Join
C to D to bisect the arc AB.
4) PERPENDICULAR AT A POINT ON A
LINE
1. At point O, draw a semicircle of any
radius to touch the line at a and b.
2. With compass at a greater radius,
strike arcs from a and b.
5) PARALLEL LINE TO A LINE WITH A
GIVEN DISTANCE.
AB is the given line, C is the given distance.
1. From any two points well apart on
AB, draw two arcs of radius equal to
C.
2. Draw a line tangential to the two
arcs to give required line.
6) DIVISION OF A LINE INTO EQUAL
PARTS
AB is the given line.
1. Draw a line AC at any angle.
2. On line AC, make three convenient
equal divisions.
3. Join the last division with B and draw
parallel lines as shown.
4. CONSTRUCTIONS OF ANGLES
TERMINOLOGY
.
NAMES OF ANGLES
7) CONSTRUCTION OF A 60° AND 30° ANGLES
8) CONSTRUCTION OF A 45° AND 90° ANGLES
If two lines are pivoted
as shown in the
diagram, as one line
opens they form an
angle. If the rotation is
continued the line will
cover a full circle. The
unit for measuring an
angle is a
5. CONSTRUCTION OF TRIANGLES
TERMINOLOGY
A triangle is a plane figure
bounded by three straight
lines.
Triangles are named according
to the length of their sides or
the magnitude of their angles.
EQUILATERAL
All angles 60°.
All sides equal.
ISOSCELES
Base angles equal.
Opposite sides equal
RIGHT ANGLE
One angle is 90°.
All sides of different length.
OBTUSE ANGLE
One angle is greater than 90°. All sides of
different length.
SCALENE
All angles different. All sides of
different length.
6. CONSTRUCTION OF TRIANGLES
9) TO CONSTRUCT AN EQUILATERAL TRIANGLE
1.Draw a line AB, equal to the length of the side.
2.With compass point on A and radius AB, draw an
arc as shown above.
10) TO CONSTRUCT AN ISOSCELES TRIANGLE, GIVEN
BASE AND VERTICAL HEIGHT
1.Draw line AB.
2.Bisect AB and mark the vertical height.
ABC is the required isosceles triangle.
11) TO CONSTRUCT A RIGHT-ANGLE TRIANGLE
1.Draw AB. From A construct angle CAB.
2.Bisect AB. Produce the bisection to cut AC at O.
3.With centre O and radius OA, draw semi-circle to
find C.
Complete the triangle
12) TO CONSTRUCT A TRIANGLE, GIVEN THE BASE
ANGLES & THE ALTITUDE
1.Draw a line AB. Construct CD parallel to AB so that the
distance between them is equal to the latitude.
2.From any point E, on CD, draw CÊF & DÊG so that they cut
AB in F & G respectively.
3.Since CÊF = EFG & DÊG = EĜF (alternate angles), then
EFG is the required triangle.
7. THE CIRCLE
PARTS OF A CIRCLE
13) TO FIND THE CENTRE OF A
GIVEN ARC
1. Draw two chords, AC and BD.
2. Bisect AC and BD as shown. The
bisectors will intersect at E.
3. The centre of the arc is point E.
14) TO FIND THE CENTRE OF
CIRCLES (METHOD 1)
1. Draw two horizontal lines facing one
another across the circle at a place
approximately halfway from the top
to the centre of the circle. These lines
pass through the circle form points A,
B, C and D.
2. Bisect these two lines. Where these two
bisect lines intersect, thus the centre
of the given circle.
15) TO FIND THE CENTRE OF
CIRCLES (METHOD 2)
1. Draw a horizontal line across the
circle at a place approx. halfway from
the top to the centre of the circle.
2. Draw perpendicular lines downward
from A and B. Where these lines cross
the circle forms C & D.
3. Draw a line from C to B and from A to
D. Where these lines cross is the exact
centre of the given circle.
8. QUADRILATERALS
TERMINOLOGY
The quadrilateral is a plane figure bounded by four straight sides
SQUARE
All four sides equal.
All angles 90:.
RECTANGLE
Opposite sides of
equal.
All angle 90:.
RHOMBUS
All four sides equal.
Opposite angles
equal.
PARALLELOGRAM
Opposite sides
equal.
Opposite angles
equal.
TRAPEZIUM
Two parallel
sides.
Two pairs of
angles equal.
16) TO CONSTRUCT A SQUARE
1.Draw the side AB. From B erect
a perpendicular. Mark off the
length of side BC.
2.With centres A & C draw arcs,
radius equal to the length of the
side of the square, to intersect at
D.
ABCD is the required square.
17) TO CONSTRUCT A
PARALLELOGRAM
1.Draw AD equal to the length of one of
the sides. From A construct the known
angle. Mark off AB equal length to
other known side.
2.With compass pt. at B draw an arc
equal radius to AD. With compass pt. at
D draw an arc equal in radius to AB.
ABCD is the required parallelogram.
18) TO CONSTRUCT A RHOMBUS
1.Draw the diagonal AC.
2.From A and C draw intersecting
arcs, equal in length to the sides, to
meet at B and D.
ABCD is the required rhombus.
9. REGULAR POLYGONS
TERMINOLOGY
A polygon is a plane figure bounded by more than four straight sides. Regular polygons are named according to the number of their
sides.
PENTAGON :5 sides HEPTAGON :7 sides NONAGON :9 sides UNDECAGON :11
sides
HEXAGON :6 sides OCTAGON :8 sides DECAGON :10 sides DODECAGON :12
sides
The regular polygons drawn on this page are the figures most frequently used in geometrical drawing. Particularly the hexagon and the
octagon which can be constructed by using 60⁰ or 45⁰ set-square.
REGULAR PENTAGON
Five sides equal.
Five angles equal.
REGULAR HEXAGON
Six sides equal.
Six angles equal.
REGULAR OCTAGON
Eight sides equal.
Eight angles are equal.
IRREGULAR PENTAGON
Five sides unequal.
Five angles unequal.
RE-ENTRANT HEXAGON
One interior angle greater than
180:.
Six sides & six angles unequal.
IRREGULAR HEPTAGON
Seven sides unequal.
Seven angles unequal.
10. ) TO CONSTRUCT A19
HEXAGON, GIVEN THE
DISTANCE ACROSS THE
(A/C)CORNERS
1.Draw a vertical and horizontal
centre lines and a circle with a
diameter equal to the given
distance.
2.Step off the radius around the
circle to give six equally spaced
points, and join the points to give
the required hexagon.
20) TO CONSTRUCT A HEXAGON,
GIVEN THE DISTANCE ACROSS THE
FLATS (A/F)
1.Draw vertical and horizontal centre
lines and a circle with a diameter equal
to the given distance.
Use a 60: set-square and tee-square as
shown to give the six sides.
21) TO CONSTRUCT AN
OCTAGON, GIVEN THE DISTANCE
ACROSS CORNERS (A/C)
1.Draw vertical and horizontal
centre lines and a circle with a
diameter equal to the given
distance.
2.With a 45: set-square, draw
points on the circumference 45:
apart.
Connect these eight points by
straight lines to give the required
octagon.
11. ) TO CONSTRUCT AN22
OCTAGON, GIVEN THE
(A/C)DISTANCE ACROSS CORNERS
1.Draw vertical and horizontal centre lines and a circle with a
diameter equal to the given distance.
2.With a 45: set-square, draw points on the circumference 45:
apart.
3.Connect these eight points by straight lines to give the
required octagon.
) TO CONSTRUCT AN OCTAGON,23
GIVEN THE DISTANCE
(A/FACROSS THE FLATS
1.vertical and horizontal centre lines and a circle with
a diameter equal to the given distance.
2.Use a 45: set-square and tee-square as shown in
construction of hexagon A/F to give the eight sides.
24) TO INSCRIBE ANY REGULAR POLYGON WITHIN A CIRCLE.
e.g. PENTAGON
12. TANGENTS TO CIRCLES
TERMINOLOGY
If a disc stands on its edge on a flat surface it will touch the surface at one point. This point is known as the point of
tangency as shown in the diagram and the straight line which represents the flat plane is known as a tangent. A line
drawn from the point of tangency to the centre of the disc is called normal, and the tangent makes an angle of 90° with
the normal.
13. 25) EXTERNAL TANGENT TO TWO CIRCLES OF
DIFFERENT Ø (OPEN BELT)
1. Join the centres of circles a and b. Bisect ab to obtain the
centre c of the semicircle.
2. From the outside of the larger circle, subtract the radius
r of the smaller circle. Draw the arc of radius ad. Draw
normal Na.
3. Normal Nb is drawn parallel to normal Na. Draw the
tangent.
26) INTERNAL TANGENT TO TWO CIRCLES OF
DIFFERENT Ø (CROSS BELT)
1. Join the centres of circles a and b. Bisect ab to obtain the
centre c of the semicircle.
2. From the outside of the larger circle, add the radius r of the
smaller circle. Draw the arc of radius ad. Draw normal Na.
3. Normal Nb is drawn parallel to normal Na. Draw the
tangent.
14. JOINING OF CIRCLES
27) OUTSIDE RADIUS
Two circles of radii a and b are tangential to arc of
radius R.
1. From the centre of circle radius a, describe an arc of R +
a.
2. From the centre of circle radius b, describe an arc of R +
b.
3. At the intersection of the two arcs, draw arc radius R.
28) INSIDE RADIUS
Two circles of radii a and b are tangential to arc of radius
R.
1. From the centre of circle radius a, describe an arc of R - a.
2. From the centre of circle radius b, describe an arc of R - b.
3. At the intersection of the two arcs, draw arc radius R.
15. THE ELLIPSE
TERMINOLOGY
29) CONCENTRIC/AUXILIARY CIRCLE METHOD
1.Draw two circles around the major and minor axis.
2.Divide into twelve equal parts using 30: - 60: set-square.
3.Draw horizontal lines from the minor circle and vertical lines from the major circle.
4.The intersection points between horizontal and vertical lines are points of an ellipse.
16. AN INVOLUTE
TERMINOLOGY
There are several definitions for the involutes, none being particularly easy to follow. An involute is the path of a point
on a string as the string unwinds from a line, polygon, or circle. And it is also the locus of a point, initially on a base circle,
which moves so that its straight line distance, along a tangent to the circle, to the tangential point of contact, is equal to
the distance along the arc of the circle from the initial point to the instant point of tangency.
The involute is best visualized as the path traced out by the end of a piece of cotton when cotton is unrolled from its reel.
30) TO DRAW AN INVOLUTE OF A CIRCLE
Let the diameter of the circle is given
1. Divide the circle into 12 equal parts.
2. Draw tangents at each of the twelve
circumferential divisions point, setting off along each
tangent the length of the corresponding circular arc.
3. Draw the required curve through the points set off
and can be determined by setting off equal distances 0-1,
1-2, 2-3, and so on, along the circumference.
NOTE:
The involutes of a circle are used in the construction of involutes gear teeth. In this system, the involutes form the face and a part
of the flank of the teeth of gear wheels; the outlines of the teeth of racks are straight lines.