Unit 1 Projection of straight lines I.pdf

ORTHOGRAPHIC PROJECTIONS
OF POINTS, LINES & PLANES

To draw projections of any object,
one must have following information:
A) OBJECT
{With its description, well defined}
B) OBSERVER
{Always observing perpendicular to resp. Ref. Plane}
C) LOCATION OF OBJECT
{Means its position with reference to H.P. & V.P.}
2

NOTATIONS
Following notations should be followed while naming
Different views in orthographic projections.
IT’S FRONT VIEW a´ a´ b´
Same system of notations should be followed
incase numbers, like 1, 2, 3 – are used.
OBJECT POINT A LINE AB
IT’S TOP VIEW a a b
IT’S SIDE VIEW a´´ a´´ b´´
TERMS ‘ABOVE’ & ‘BELOW’ WITH RESPECT TO H.P.
AND TERMS ‘INFRONT’ & ‘BEHIND’ WITH RESPECT TO V.P.
3

X
Y
1ST Quad.
2nd Quad.
3rd Quad. 4th Quad.
X Y
VP
HP
Observer
This quadrant pattern, if observed along x-y line (in red arrow
direction) will exactly appear as shown on right side and hence
it is further used to understand illustration properly.
4

HP
VP
a´
a
A
POINT A IN
1ST QUADRANT
OBSERVER
VP
HP
POINT A IN
2ND QUADRANT
OBSERVER
a´
a
A
OBSERVER
a
a´
POINT A IN
3RD QUADRANT
HP
VP
A
OBSERVER
a
a´
POINT A IN
4TH QUADRANT
HP
VP
A
Point A is
placed In
different
quadrants
and it’s FV & TV
are brought in
same plane for
Observer to see
clearly.
FV is visible as
it is a view on
VP. But as TV is
is a view on HP,
it is rotated
downward 900,
in clockwise
direction. The
front part of
HP comes below
XY line and the
part behind VP
comes above.
5

A
a
a´
A
a
a´
A
a
a´
X
Y
X
Y
X
Y
For TV
For TV
For TV
POINT A ABOVE HP
& INFRONT OF VP
POINT A IN HP
& INFRONT OF VP
POINT A ABOVE HP
& IN VP
PROJECTIONS OF A POINT IN FIRST QUADRANT
PICTORIAL
PRESENTATION
PICTORIAL
PRESENTATION
ORTHOGRAPHIC PRESENTATIONS
OF ALL ABOVE CASES.
X Y
a
a´
VP
HP
X Y
a´
VP
HP
a X Y
a
VP
HP
a´
FV above XY,
TV below XY.
FV above XY,
TV on XY.
FV on XY,
TV below XY.
6

SIMPLE CASES OF THE LINE
1. A vertical line (line perpendicular to HP & parallel to VP)
2. Line parallel to both HP & VP.
3. Line inclined to HP & parallel to VP.
4. Line inclined to VP & parallel to HP.
5. Line inclined to both HP & VP.
PROJECTIONS OF STRAIGHT LINES
INFORMATION REGARDING A LINE MEANS:
• It’s length
• Position of it’s ends with HP & VP
• It’s inclinations with HP & VP will be given.
AIM:- To draw it’s projections - means FV & TV.
7

X
Y
X
Y
b´
a´
b
a
a (b)
a´
b´
B
A
TV
FV
A
B
X Y
H.P.
V.P. a´
b´
a (b)
FV
TV
X Y
H.P.
V.P.
a b
a´ b´
FV
TV
For TV
For TV
Note:
FV is a vertical line
Showing True Length
&
TV is a point.
Note:
FV & TV both are
// to XY
&
both show T. L.
1.
2.
A line
perpendicular
to HP
&
parallel to VP
A line
// to HP
&
// to VP
Orthographic Pattern
Orthographic Pattern
(Pictorial Presentation)
(Pictorial Presentation)
8

A line inclined to HP
and
parallel to VP
(Pictorial presentation)
X
Y
A
B
b´
a´
b
a


A line inclined to VP
and
parallel to HP
Ø
a b
a´
b´
B
A
Ø
X Y
H.P.
V.P.
T.V.
a b
a´
b´

X Y
H.P.
V.P.
Ø
a
b
a´ b´
TV
FV
TV inclined to XY
FV parallel to XY
3.
4.
FV inclined to XY
TV parallel to XY
Orthographic Projections
9

a´
X
Y
EXAMPLE PROBLEMS ON POINTS
PROBLEM 1:
A point A is 20 mm above HP and 30 mm in front of VP. Draw its projections
Solution steps:
1) Draw reference line XY.
2) Mark a point a´ at a distance of 20 mm above XY.
3) Through this point draw a perpendicular line to XY and mark the top view a at a distance of
30 mm below XY.
a
30
20 HP
a
VP
A
a´
X Y
a
20
30
10
Orthographic projection

PROBLEM 2:
A point D is 20 mm below HP and 30 mm in front of VP. Draw its projections.
Solution steps:
1) Draw reference line XY.
2) Mark a point d´ at a distance of 20 mm below XY.
3) Through this point draw a perpendicular line to XY and mark the top view d at a distance of
30 mm above XY.
d
20
30
D
d´
HP
X
Y
X Y
30
20
d
d´
11
Orthographic projection

PROBLEM 3:
Draw the projections of the following points on the same ground line, keeping the distance
between projectors equal to 25 mm.
(i) Point A, 20 mm above HP, 25 mm behind VP;
(ii) Point B, 25 mm below HP, 20 mm behind VP;
(iii) Point C, 20 mm below HP, 30 mm in front of VP;
(iv) Point D, 20 mm above HP, 25 mm in front of VP;
(v) Point E, on HP, 25 mm behind VP;
(vi) Point F, on VP, 30 mm above HP;
X Y
25
20
a
a´
12
20
25
c
b
c´
b´
30
20
20
25
`
d
d´
e
e´
25
30
f
f´
Solution:

PROBLEM 4:
Draw projections of a 80 mm long line PQ. Its end P is 10 mm above HP and 10 mm in front of VP.
The line is parallel to VP and inclined to HP at 30°.
Solution steps:
1) Draw the plan and elevations of the end point P.
2) Draw plan PQ of the line at an angle of 30° to XY.
3) Draw the projector of Q.
4) From the elevation of end point P draw a line parallel to XY meeting projector of Q at Q´.
5) P´Q´ is the elevation and PQ is the plan of the line.
30°
X Y
P Q
P´
Q´
10
10
13
Parallel to VP and inclined to HP

PROBLEM 5:
A straight line AB of 40 mm length has one of its ends A, at 10 mm from the HP and 15 mm from
the VP. Draw the projections of the line if it is parallel to the VP and inclined at 30° to the HP.
Assume the line to be located in each of the four quadrants by turns. (EXAMPLE)
30°
X Y
a b
a´
b´
15
10
14
Parallel to VP and inclined to HP
30°
X Y
a
b
a´
15
10
b´
15
10
X Y
30°
a
a´
b
b´
10
15
X Y
a´
a 30°
b
b´
( Quadrant 1) (Quadrant 2)
(Quadrant 3)
(Quadrant 4)

PROBLEM 6:
A straight line AB of 40 mm length is parallel to the HP and inclined at 30° to the VP. Its end point
A is 10 mm from the HP and 15 mm from the VP. Draw the projections of the line AB, assuming it
to be located in all the four quadrants by turns.
15
Parallel to HP and inclined to VP
30°
X Y
a
b
a´
15
10
b´
15
10
X Y
30°
a
a´
b
b´
10
15
X Y
a´
a
30°
b
b´
30°
X Y
a
b
a´
15
10
b´
( Quadrant 1)
( Quadrant 4)
( Quadrant 3)
( Quadrant 2)

X
Y
a´
b´
a b
B
A


For TV
T.V.
X
Y
a´
b´
a b


T.V.
For TV
B
A
X Y


H.P.
V.P.
a
b
FV
TV
a´
b´
A Line inclined to both
HP and VP
5.
Note:-
Both FV & TV are inclined to
XY.
(No view is parallel to XY)
Both FV & TV are reduced
lengths
(No view shows True Length)
FV is seen on VP clearly.
To see TV clearly, HP is rotated
900 downwards,
Hence it comes below XY.
On removal of object
i.e. Line AB
FV as a image on VP.
TV as a image on HP,
16

X Y
H.P.
V.P.
X Y

H.P.
V.P.
a
b
TV
a´
b´
FV
TV
b2
b1´
TL
X Y


H.P.
V.P.
a
b
FV
TV
a´
b´
Here TV (ab) is not // to XY
line
Hence it’s corresponding FV
a’ b’ is not showing
True Length &
True Inclination with HP.
In this sketch, TV is rotated
and made // to XY line.
Hence it’s corresponding
FV, a’ b1’is showing
True Length
&
True Inclination with HP.
Note the procedure
When FV & TV known,
How to find True Length.
(Views are rotated to determine
True Length & it’s inclinations
with HP & VP).
Note the procedure
When True Length is known,
How to locate FV & TV.
(Component a-1 of TL is drawn
which is further rotated
to determine FV)
1
a
a´
b´
1´
b

b1´


b1
Ø
Means FV & TV of Line AB
are shown below, with their
apparent inclinations  & 
Here a -1 is component
of TL ab1 gives length of FV.
Hence it is brought upto
Locus of a’ and further rotated
to get point b’. a’ b’ will be FV.
Similarly drawing component
of other TL (a’ b1‘) TV can be drawn.

17

Diagram showing graphical relations
among all important parameters of this topic.
True Length is never rotated. It’s horizontal component is
drawn & it is further rotated to locate view.
Views are always rotated, made horizontal & further
extended to locate TL,  & Ø
Also remember
TEN important
parameters
to be remembered
with notations
used here onward
Ø



1) True Length (TL) – a’ b1’ & a b1
2) Angle of TL with HP -
3) Angle of TL with VP –
4) Angle of FV with XY –
5) Angle of TV with XY –
6) LTV (length of FV) – Component (a-1)
7) LFV (length of TV) – Component (a’-1’)
8) Position of A- Distances of a & a’ from XY
9) Position of B- Distances of b & b’ from XY
10) Distance between End Projectors
X Y
H.P.
V.P.
1
a
b

b1
Ø
LFV
a´
b´
1´
b1´


LTV
Distance between
End Projectors.

 & Construct with a’
Ø 
& Construct with a
b & b1 on same locus.
b’ & b1’ on same locus.
NOTE
18

a´
b´
a
b
X Y
b´1
b1
Ø

PROBLEM 7:
Line AB is 75 mm long and it is 300 & 400 inclined to HP & VP respectively. End A is
12mm above HP and 10 mm in front of VP. Draw projections. Line is in 1st quadrant.
Solution steps:
1) Draw XY line and one projector.
2) Locate a´ 12mm above XY line
& a 10mm below XY line.
3) Take 300 angle from a´ & 400
from a and mark TL, i.e.,
75mm on both lines. Name
those points b1´ and b
respectively.
4) Draw horizontal component of
TL a b1 from point b1 and
name it 1. (the length a-1
gives length of FV as we have
seen already)
5) Extend it up to locus of a and
rotating a’ as center locate b´
as shown. Join a´ b´ as FV.
6) From b´ drop a projector
downward & get point b. Join
a & b, i.e., TV.
LFV
TL
TL
FV
TV
19
1
INCLINED TO HP & VP

X Y
a
a´
b1
1
b´ 1
b´
LFV
550
b
PROBLEM 8:
Line AB 75mm long makes 450 inclination with VP while it’s FV makes 550. End A is 10 mm above HP
and 15 mm in front of VP. If line is in 1st quadrant draw it’s projections and find it’s inclination with HP.
LOCUS OF b1
LOCUS OF b1´
Solution Steps:-
1.Draw xy line.
2.Draw one projector for a’ & a
3.Locate a´ 10mm above XY & a 15 mm below
XY.
4.Draw a line 450 inclined to XY from point a and
cut TL 75 mm on it and name that point b1.
5.Draw locus from point b1.
6.Take 550 angle from a´ for FV above XY line.
7.Draw a vertical line from b1 up to locus of a
and name it 1. It is horizontal component of
TL & is LFV.
8.Continue it to locus of a´ and rotate upward up
to the line of FV and name it b´. This a´ b´ line is
FV.
9. Drop a projector from b´ on locus from point
b1 and name intersecting point b. Line ab is TV
of line ab.
10.Draw locus from b´ and with TL distance cut
point b1´
11.Join a´ b1´ as TL and measure it’s angle α at
a´. It will be true angle of line with HP.
20
α
FINDING INCLINATION WITH HP

X
a’
Y
a
b’
500
b
600
b1
b’1
PROBLEM 9: FV of line AB is 500 inclined to XY and measures 55 mm long while it’s TV is 600
inclined to XY line. If end A is 10 mm above HP and 15 mm in front of VP, draw it’s projections,
find TL, inclinations of line with HP & VP.
Solution steps:
1.Draw XY line and one
projector.
2.Locate a’ 10 mm above XY
and a 15 mm below XY line.
3.Draw locus from these points.
4.Draw FV 500 from a’ and
mark b’ cutting 55mm on it.
5.Similarly draw TV 600 from a
& drawing projector from b’
locate point b and join a b.
6.Then rotating views as
shown, locate True Lengths ab1
& a’b1’ and their angles with
HP and VP.
21
FINDING TL AND INCLINATIONS

X Y
a’
1’
a
b’1
LTV
b1
1
b’
b
LFV


PROBLEM 10:-
Line AB is 75 mm long. It’s FV and TV measure 50 mm & 60 mm long respectively. An end is 10 mm
above HP and 15 mm in front of VP. Draw projections of line AB if end B is in first quadrant. Find angle
with HP and VP.
22
SOLUTION STEPS:
1.Draw XY line and one projector.
2.Locate a’ 10 mm above XY and
a 15 mm below XY line.
4.Cut 60mm distance on locus of a’
& mark 1’ on it as it is LTV.
5.Similarly cut 50mm on locus of a
and mark point 1 as it is LFV.
6.From 1’ draw a vertical line upward
and from a’ taking TL (75mm ) in
compass, mark b’1 point on it.
Join a’ b’1 points.
7. Draw locus from b’1
8. With same steps below get b1 point
and draw also locus from it.
9. Now rotating one of the components
i.e., a-1 locate b’ and join a’ with it
to get FV.
10. Locate TV similarly and measure
angles  and 
FINDING ANGLE WITH HP & VP

X Y
c’
c
LOCUS OF d
d d1
d’1


LOCUS OF d’
PROBLEM 11:- TV of a 75 mm long line CD, measures 50 mm. End C is in HP and 50 mm in front of VP.
End D is 15 mm in front of VP and it is above HP. Draw projections of CD and find angles with HP and VP.
23
SOLUTION STEPS:
1.Draw XY line and one projector.
2.Locate c’ on XY and c 50mm
below XY line.
4.Draw locus of d 15 mm below XY.
5.Cut 50mm & 75 mm distances on
locus of d from c and mark points
d & d1 as these are TV and TL.
Join both with c.
6.From d1 draw a vertical line
upward up to XY i.e., up to locus of
c’ and draw an arc as shown.
7 Then draw one projector from d
to meet this arc in d’ point & join c’
d’
8. Draw locus of d’ and cut 75 mm
on it from c’ as TL
9.Measure angles and 
FINDING ANGLE WITH HP & VP
d’

X Y
PROBLEM 9:- Two straight lines PQ and QR make an angle of 120° between them in front and top
views. PQ is 60 mm long and is parallel to and 15 mm from both H.P. and V.P. Determine the true angle
between PQ and QR, if point R is 50 mm above H.P. (EXAMPLE)
SOLUTION STEPS:
1. Draw a reference line xy. Mark point p´ at 15 mm
above xy and point p at 15 mm below xy.
2. Draw 60 mm long lines p´q´ and pq, parallel to xy.
3. Draw a line from point q´, inclined at 120° to xy such
that it meets the horizontal line at 50 mm above xy at
point r´. Join q´r´ and p´r´.
4. Draw a line from point q, inclined at 120° to xy such
that it meets the projector from r´ at a point r. Join qr
and pr.
5. As lines pq and p´q´ are parallel to xy, they represent
the true length of side PQ. Here PQ = 60 mm.
6. Draw an arc with centre p and radius pr to meet the
horizontal line from p at point r1. Project point r1 to meet
horizontal lines from point r´ at point r1
’. Join p´r1
’ to
represent the TL of the line PR. Here, PR = p´ r1
´= 94
mm.
7. Draw an arc with centre q and radius qr, to meet the
horizontal line at r2. Project point r2 to meet horizontal
lines form point r´ at point r´2. Join q´ r2
´ to represent the
TL of line QR. Here, QR = q´ r2
´ = 53mm.
8. Draw actual triangle PQR taking true lengths, i.e., 60
mm, 94 mm and 53 mm. Measure the inclined angle
PQR as the actual angle between sides PQ and QR.
Here, it is 112°.
Q
R
r´ r1
’
r´2
r2
r1
p
p’
q
q’
r
15
15
60
24
P
50
FINDING TRUE ANGLE

TRACES OF THE LINE:-
These are the points of intersections of a line ( or it’s extension ) with respect to
reference planes.
A line itself or its extension, where ever touches H.P., that point is called TRACE
OF THE LINE ON H.P. (It is called H.T.)
Similarly, a line itself or it’s extension, where ever touches V.P., that point is called
TRACE OF THE LINE ON V.P. (it is called V.T.)
V.T.:- It is a point on VP.
Hence it is called FV of a point in VP.
Hence it’s TV comes on XY line.( Here onward denoted as ‘v’)
H.T.:- It is a point on HP.
Hence it is called TV of a point in HP.
Hence it’s FV comes on XY line.( Here onward denoted as ‘h’ )
PROBLEMS INVOLVING TRACES OF THE LINE
25

Unit 1 Projection of straight lines I.pdf

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Unit 1 Projection of straight lines I.pdf