A pentagonal prism with a 25mm base and 50mm axis is resting on one of its rectangular faces on the HP. The axis is inclined at 45° to the VP.
1. Assume the prism is standing on the HP. Draw its TV showing the true pentagonal base shape.
2. Draw its FV with the axis vertical and perpendicular to the VP.
3. Incline the axis 45° to the VP. Draw the new inclined FV and project the TV.
Download the original presentation for animation and clear understanding. This Presentation describes the concepts of Engineering Drawing of VTU Syllabus. However same can also be used for learning drawing concepts. Please write to me for suggestions and criticisms here: hareeshang@gmail.com or visit this website for more details: www.hareeshang.wikifoundry.com.
Download the original presentation for animation and clear understanding. This Presentation describes the concepts of Engineering Drawing of VTU Syllabus. However same can also be used for learning drawing concepts. Please write to me for suggestions and criticisms here: hareeshang@gmail.com or visit this website for more details: www.hareeshang.wikifoundry.com.
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Projection of solids(thedirectdata.com)
1. SOLIDS
To understand and remember various solids in this subject properly,
those are classified & arranged in to two major groups.
Group A Group B
Solids having top and base of same shape Solids having base of some shape
and just a point as a top, called apex.
Cylinder Cone
Prisms Pyramids
Triangular Square Pentagonal Hexagonal Triangular Square Pentagonal Hexagonal
Cube Tetrahedron
( A solid having ( A solid having
six square faces) Four triangular faces)
2. SOLIDS
Dimensional parameters of different solids.
Square Prism Square Pyramid Cylinder Cone
Apex Apex
Top
Rectangular Slant
Face Edge Triangular
Longer Base Face Base Base
Base
Edge
Corner of Edge Edge Corner of
Generators
base of of base
Imaginary lines
Base Base
generating curved surface
of cylinder & cone.
Sections of solids( top & base not parallel) Frustum of cone & pyramids.
( top & base parallel to each other)
3. STANDING ON H.P RESTING ON H.P LYING ON H.P
On it’s base. On one point of base circle. On one generator.
(Axis perpendicular to Hp (Axis inclined to Hp (Axis inclined to Hp
And // to Vp.) And // to Vp) And // to Vp)
F.V. F.V. F.V.
X Y
While observing Fv, x-y line represents Horizontal Plane. (Hp)
X While observing Tv, x-y line represents Vertical Plane. (Vp) Y
T.V. T.V. T.V.
STANDING ON V.P RESTING ON V.P LYING ON V.P
On it’s base. On one point of base circle. On one generator.
Axis perpendicular to Vp Axis inclined to Vp Axis inclined to Vp
And // to Hp And // to Hp And // to Hp
4. STEPS TO SOLVE PROBLEMS IN SOLIDS
Problem is solved in three steps:
STEP 1: ASSUME SOLID STANDING ON THE PLANE WITH WHICH IT IS MAKING INCLINATION.
( IF IT IS INCLINED TO HP, ASSUME IT STANDING ON HP)
( IF IT IS INCLINED TO VP, ASSUME IT STANDING ON VP)
IF STANDING ON HP - IT’S TV WILL BE TRUE SHAPE OF IT’S BASE OR TOP:
IF STANDING ON VP - IT’S FV WILL BE TRUE SHAPE OF IT’S BASE OR TOP.
BEGIN WITH THIS VIEW:
IT’S OTHER VIEW WILL BE A RECTANGLE ( IF SOLID IS CYLINDER OR ONE OF THE PRISMS):
IT’S OTHER VIEW WILL BE A TRIANGLE ( IF SOLID IS CONE OR ONE OF THE PYRAMIDS):
DRAW FV & TV OF THAT SOLID IN STANDING POSITION:
STEP 2: CONSIDERING SOLID’S INCLINATION ( AXIS POSITION ) DRAW IT’S FV & TV.
STEP 3: IN LAST STEP, CONSIDERING REMAINING INCLINATION, DRAW IT’S FINAL FV & TV.
GENERAL PATTERN ( THREE STEPS ) OF SOLUTION:
GROUP B SOLID. GROUP A SOLID. GROUP B SOLID. GROUP A SOLID.
CONE CYLINDER CONE CYLINDER
AXIS AXIS
AXIS AXIS INCLINED HP INCLINED HP
AXIS AXIS VERTICAL INCLINED HP
VERTICAL INCLINED HP
er AXIS er AXIS
AXIS AXIS TO VP AXIS TO VP
INCLINED VP AXIS INCLINED INCLINED
INCLINED VP VP VP
Three steps Three steps Three steps Three steps
If solid is inclined to Hp If solid is inclined to Hp If solid is inclined to Vp If solid is inclined to Vp
Study Next Twelve Problems and Practice them separately !!
5. CATEGORIES OF ILLUSTRATED PROBLEMS!
PROBLEM NO.1, 2, 3, 4 GENERAL CASES OF SOLIDS INCLINED TO HP & VP
PROBLEM NO. 5 & 6 CASES OF CUBE & TETRAHEDRON
PROBLEM NO. 7 CASE OF FREELY SUSPENDED SOLID WITH SIDE VIEW.
PROBLEM NO. 8 CASE OF CUBE ( WITH SIDE VIEW)
PROBLEM NO. 9 CASE OF TRUE LENGTH INCLINATION WITH HP & VP.
PROBLEM NO. 10 & 11 CASES OF COMPOSITE SOLIDS. (AUXILIARY PLANE)
PROBLEM NO. 12 CASE OF A FRUSTUM (AUXILIARY PLANE)
6. Solution Steps :
Problem 1. A square pyramid, 40 Triangular face on Hp , means it is lying on Hp:
mm base sides and axis 60 mm long, 1.Assume it standing on Hp.
2.It’s Tv will show True Shape of base( square)
has a triangular face on the ground 3.Draw square of 40mm sides with one side vertical Tv &
and the vertical plane containing the taking 50 mm axis project Fv. ( a triangle)
axis makes an angle of 450 with the 4.Name all points as shown in illustration.
5.Draw 2nd Fv in lying position I.e.o’c’d’ face on xy. And project it’s Tv.
VP. Draw its projections. Take apex 6.Make visible lines dark and hidden dotted, as per the procedure.
nearer to VP 7.Then construct remaining inclination with Vp
( Vp containing axis ic the center line of 2nd Tv.Make it 450 to xy as
shown take apex near to xy, as it is nearer to Vp) & project final Fv.
o’
a’1 b’1
X a’b’ c’
d’ o’1 Y
d’1 c’1
a1
a d d1 a1
o1
o
b c c1 b1 (APEX
NEARER (APEX
TO V.P). AWAY
For dark and dotted lines
FROM V.P.)
1.Draw proper outline of new view DARK. 2. Decide direction of an observer.
3. Select nearest point to observer and draw all lines starting from it-dark.
4. Select farthest point to observer and draw all lines (remaining)from it- dotted.
7. Q Draw the projections of a pentagonal prism , base 25 mm side and axis 50 mm long,
resting on one of its rectangular faces on the H.P. with the axis inclined at 45º to the V.P.
As the axis is to be inclined with the VP, in the first view it must be kept perpendicular to the
VP i.e. true shape of the base will be drawn in the FV with one side on XY line
b’ 2’
b1’ 21’
a’ 1’ c’ 3’ a1’ 31’
c1’ 11’
X e’ 5’ d’ 4’ e1’ d1’ 41’ Y
45º 51’
25 c
d
d
a e b c b
e
a
3
50
4
2
5
1
1 5 2 4 3
8. Solution Steps:
Problem 2: Resting on Hp on one generator, means lying on Hp:
A cone 40 mm diameter and 50 mm axis 1.Assume it standing on Hp.
is resting on one generator on Hp 2.It’s Tv will show True Shape of base( circle )
which makes 300 inclination with Vp 3.Draw 40mm dia. Circle as Tv &
taking 50 mm axis project Fv. ( a triangle)
Draw it’s projections. 4.Name all points as shown in illustration.
5.Draw 2nd Fv in lying position I.e.o’e’ on xy. And
For dark and dotted lines
1.Draw proper outline of new vie project it’s Tv below xy.
DARK. 6.Make visible lines dark and hidden dotted,
2. Decide direction of an observer. as per the procedure.
3. Select nearest point to observer 7.Then construct remaining inclination with Vp
and draw all lines starting from ( generator o1e1 300 to xy as shown) & project final Fv.
it-dark.
4. Select farthest point to observer o’
and draw all lines (remaining) a’1
from it- dotted.
h’1 b’1
g’1
f’1 c’
X a’ h’b’ c’ g f’ d’ e’ o’
e’1 d’1 1 Y o1
30
’
g g1
g1 o1
h f f1 h1 h1
f1 a1
a e e1 a1 o1
e1 b1
b d d1 b1
d1
c c1 c1
9. Solution Steps:
Problem 3: Resting on Vp on one point of base, means inclined to Vp:
A cylinder 40 mm diameter and 50 mm 1.Assume it standing on Vp
2.It’s Fv will show True Shape of base & top( circle )
axis is resting on one point of a base 3.Draw 40mm dia. Circle as Fv & taking 50 mm axis project Tv.
circle on Vp while it’s axis makes 450 ( a Rectangle)
with Vp and Fv of the axis 350 with Hp. 4.Name all points as shown in illustration.
5.Draw 2nd Tv making axis 450 to xy And project it’s Fv above xy.
Draw projections.. 6.Make visible lines dark and hidden dotted, as per the procedure.
7.Then construct remaining inclination with Hp
( Fv of axis I.e. center line of view to xy as shown) & project final Tv.
4’d’ d’ 4’
3’
1’ a’ c’ a’ c’ 3’
1’
2’ b’ b’ 2’
X 350
Y
a bd c 450 c1
d1
b1
a1
3
4
2
1 24 3
1
10. Solution Steps :
1.Assume it standing on Hp but as said on apex.( inverted ).
Problem 4:A square pyramid 30 mm base side 2.It’s Tv will show True Shape of base( square)
3.Draw a corner case square of 30 mm sides as Tv(as shown)
and 50 mm long axis is resting on it’s apex on Hp,
Showing all slant edges dotted, as those will not be visible from top.
such that it’s one slant edge is vertical and a
4.taking 50 mm axis project Fv. ( a triangle)
triangular face through it is perpendicular to Vp. 5.Name all points as shown in illustration.
Draw it’s projections. 6.Draw 2nd Fv keeping o’a’ slant edge vertical & project it’s Tv
7.Make visible lines dark and hidden dotted, as per the procedure.
8.Then redrew 2nd Tv as final Tv keeping a1o1d1 triangular face
perpendicular to Vp I.e.xy. Then as usual project final Fv.
a’ b’d’ c’ a’1
d’1 b’1
c’1
X o’ o’1 Y
d d1
a b
o c a1
o1 b1 c1
11. Solution Steps:
Problem 5: A cube of 50 mm long 1.Assuming standing on Hp, begin with Tv,a square with all sides
edges is so placed on Hp on one equally inclined to xy.Project Fv and name all points of FV & TV.
corner that a body diagonal is 2.Draw a body-diagonal joining c’ with 3’( This can become // to xy)
parallel to Hp and perpendicular to 3.From 1’ drop a perpendicular on this and name it p’
Vp Draw it’s projections. 4.Draw 2nd Fv in which 1’-p’ line is vertical means c’-3’ diagonal
must be horizontal. .Now as usual project Tv..
6.In final Tv draw same diagonal is perpendicular to Vp as said in problem.
Then as usual project final FV.
a’1
d’1
d’1
a’ b’d’ c’
3’
c’1
3’ 1’ 1’ 1’
X d
Y
d1
a c a1 c1
b b1
12. Problem 6:A tetrahedron of 50 mm Solution Steps
long edges is resting on one edge on As it is resting assume it standing on Hp.
Hp while one triangular face containing Begin with Tv , an equilateral triangle as side case as shown:
this edge is vertical and 450 inclined to First project base points of Fv on xy, name those & axis line.
Vp. Draw projections. From a’ with TL of edge, 50 mm, cut on axis line & mark o’
(as axis is not known, o’ is finalized by slant edge length)
IMPORTANT: Then complete Fv.
Tetrahedron is a In 2nd Fv make face o’b’c’ vertical as said in problem.
special type And like all previous problems solve completely.
of triangular
pyramid in which
base sides & o’1
slant edges are o’
equal in length. TL
Solid of four faces. a’1
Like cube it is also 900
described by One X a’ b’ b’1
c’ c’1 Y
dimension only.. 450
Axis length c c1
generally not given.
a o a1 o1
b b1
13. FREELY SUSPENDED SOLIDS:
Positions of CG, on axis, from base, for different solids are shown below.
H
CG
H/2 CG
H/4
GROUP A SOLIDS GROUP B SOLIDS
( Cylinder & Prisms) ( Cone & Pyramids)
14. Solution Steps:
Problem 7: A pentagonal pyramid In all suspended cases axis shows inclination with Hp.
30 mm base sides & 60 mm long axis, 1.Hence assuming it standing on Hp, drew Tv - a regular pentagon,corner case.
is freely suspended from one corner of 2.Project Fv & locate CG position on axis – ( ¼ H from base.) and name g’ and
base so that a plane containing it’s axis Join it with corner d’
remains parallel to Vp. 3.As 2nd Fv, redraw first keeping line g’d’ vertical.
Draw it’s three views. 4.As usual project corresponding Tv and then Side View looking from.
LINE d’g’ VERTICAL d”
o’ d’
c’e’ e” c”
FOR SIDE VIEW
g’
H a’b’
a” b”
g’
H/4 o”
IMPORTANT: a’ b’ c’ e’ d’ Y
X
When a solid is freely e1
e
suspended from a a1
corner, then line a
d1
joining point of o do
1
contact & C.G. b b1
remains vertical. c c1
( Here axis shows
inclination with Hp.)
So in all such cases,
assume solid standing
on Hp initially.)
15. Solution Steps: Problem 8:
1.Assuming it standing on Hp begin with Tv, a square of corner case. A cube of 50 mm long edges is so placed
2.Project corresponding Fv.& name all points as usual in both views. on Hp on one corner that a body diagonal
3.Join a’1’ as body diagonal and draw 2nd Fv making it vertical (I’ on xy) through this corner is perpendicular to Hp
4.Project it’s Tv drawing dark and dotted lines as per the procedure. and parallel to Vp Draw it’s three views.
5.With standard method construct Left-hand side view.
( Draw a 450 inclined Line in Tv region ( below xy).
Project horizontally all points of Tv on this line and
reflect vertically upward, above xy.After this, draw
horizontal lines, from all points of Fv, to meet these
lines. Name points of intersections and join properly. a’’
For dark & dotted lines
locate observer on left side of Fv as shown.)
d’’ b’’
a’ b’d’ c’
c’’
X 1’ Y
1’
d d1 1’
a c a1 c1
b b
16. Problem 9: A right circular cone, This case resembles to problem no.7 & 9 from projections of planes topic.
40 mm base diameter and 60 mm In previous all cases 2nd inclination was done by a parameter not showing TL.Like
long axis is resting on Hp on one Tv of axis is inclined to Vp etc. But here it is clearly said that the axis is 40 0 inclined
point of base circle such that it’s to Vp. Means here TL inclination is expected. So the same construction done in those
axis makes 450 inclination with Problems is done here also. See carefully the final Tv and inclination taken there.
Hp and 400 inclination with Vp. So assuming it standing on HP begin as usual.
Draw it’s projections.
o’ o’1
a’1
h’1 b’1
g’1 c’1
450 f’1 d’1
X a’ h’b’ c’ g’ f’ d’ e’
e’1
y
Axis True Length
g g1 400
h f h1 f1
Axis Tv Length
a e a1 1 e1
o1
Locus of
Center 1
b1 d1 1
b d
c c1
Axis Tv Length
17. Problem 10: A triangular prism,
40 mm base side 60 mm axis
is lying on Hp on one rectangular face
with axis perpendicular to Vp.
One square pyramid is leaning on it’s face F.V.
centrally with axis // to vp. It’s base side is
30 mm & axis is 60 mm long resting on Hp
on one edge of base.Draw FV & TV of
both solids.Project another FV
on an AVP 450 inclined to VP. X Y
450
Steps :
Draw Fv of lying prism
( an equilateral Triangle)
And Fv of a leaning pyramid. T.V.
Project Tv of both solids.
Draw x1y1 450 inclined to xy
and project aux.Fv on it. Aux.F.V.
Mark the distances of first FV
from first xy for the distances
of aux. Fv from x1y1 line.
Note the observer’s directions
Shown by arrows and further
steps carefully.
18. Problem 11:A hexagonal prism of
base side 30 mm longand axis 40 mm long,
is standing on Hp on it’s base with
one base edge // to Vp.
A tetrahedron is placed centrally
on the top of it.The base of tetrahedron is
a triangle formed by joining alternate corners
of top of prism..Draw projections of both solids. o’
Project an auxiliary Tv on AIP 450 inclined to Hp.
STEPS:
Draw a regular hexagon as Tv of
standing prism With one side // to xy Y1
and name the top points.Project it’s Fv – a’ b’ f’ c’ e’ d’
a rectangle and name it’s top.
Now join it’s alternate corners Fv
a-c-e and the triangle formed is base
of a tetrahedron as said. X Y Aux.Tv
Locate center of this triangle e1 o1
450
& locate apex o
f e
Extending it’s axis line upward f1 d1
mark apex o’
By cutting TL of edge of tetrahedron
equal to a-c. and complete Fv Tva o d a1 c1
of tetrahedron.
Draw an AIP ( x1y1) 450 inclined to xy b1
And project Aux.Tv on it by using similar b c
Steps like previous problem. X1
19. Problem 12: A frustum of regular hexagonal pyrami is standing on it’s larger base
On Hp with one base side perpendicular to Vp.Draw it’s Fv & Tv.
Project it’s Aux.Tv on an AIP parallel to one of the slant edges showing TL.
Base side is 50 mm long , top side is 30 mm long and 50 mm is height of frustum.
Fv
AIP // to slant edge
1’ 2’5’ 3’4’ Y1
Showing true length
i.e. a’- 1’
4
5 3
1 2
X a’ b’ e’ c’ d’ Y Aux.Tv
e d1
c1
d e1
Tv 5
4 X1 a1 b1
a 1
3
2
c
b
21. Q13.22: A hexagonal pyramid base 25 mm side and axis 55 mm long has one of its slant
edge on the ground. A plane containing that edge and the axis is perpendicular to the H.P.
and inclined at 45º to the V.P. Draw its projections when the apex is nearer to the V.P. than
the base.
The inclination of the axis is given indirectly in this problem. When the slant edge of a pyramid rests
on the HP its axis is inclined with the HP so while decidingHP and the axis of the solid must be
The vertical plane containing the slant edge on the first view the axis is seen in the TV
kepto1d1 for drawingHP i.e. trueFV draw an auxiliary be seen inY1 at 45º from d1when drawing
as perpendicular to auxiliary shape of the base will plane X1 the TV. Secondly o1
hexagon in the TV draw projectorsthe corners at the extremeto f1 perpendicular to X1Y1 and
extended. Then we have to keep from each point i.e. a1 ends.
mark the points measuring their distances in the FV from old XY line.
o’
f1’
a’
a1’
e1’
b’ X1
f’ b1’
c1’
c’ d1’
e’
b’ c’ d’ o’
X a’ f’ e’ d’ Y
f1 o1’
e1
f e
a
d d1 a1
o 45º Y1
o1
b c c1 b1