2. Performance of Non-Engineered masonry Buildings
During Earthquakes
Stone masonry buildings tend to perform poorly in
earthquakes owing to the low strength of the stone and
mortar used and the lack of adequate wall connections
The failure pattern of such masonry structures during
earthquake can be classified as
7. Simplicity and symmetry in plan and elevation
Building Height
In general, stone masonry buildings should not be taller
than 2 storeys when built in cement mortar, and 1 storey
when built in lime or mud mortar
Roofs
Lighter roofs are preferable to heavy roofs. Sheeted roofs
are better than tiled roofs All elements of a roof should
be so integrated that it may have the capability of acting
as one stiff unit in plan for holding the walls together
EARTHQUAKE PROTECTION MESURES:-
Architectural Design Features:-
8. Floors
For holding the walls together, the floor elements should
have full bearing on the walls
Opening in Walls
For better seismic behavior openings should be as small and
centrally located as functionally feasible
Enclosed space
Within a building, smaller rooms with bonded long and
short walls forming a crate like enclosure, are seismically
stronger than rooms with long uninterrupted masonry walls
9.
10. Fall of roof because of Inadequate
connection between roof and wall 1- Earthquake 2- Flat joisted
roof 3- Fractional support, no connection 4- Out of phase
motion 5- Crack
1 1
2 3
5
1
4
11. Quality of Construction and Maintenance
Good quality of building materials - mortar and
building units of good strength
Proper bond so as to break vertical joints in walls
Construction of walls truly vertical
Proper continuity at corners and wall junctions
12. The masonry
walls should be built in
construction lifts not
exceeding 600mm. Through-
stones (each extending
over full thickness of wall) or
a pair of overlapping
bond-stones (each extending
over at least ¾ths
thickness of wall) must be
used at every 600mm
along the height and at a
maximum spacing of 1.2m
along the length (Figure 3).
13. Ensure proper wall construction
The wall thickness should not exceed 450mm.
Round stone boulders should not be used in the
Construction Instead, the stones should be
shaped using chisels and hammer
Control on overall dimensions and heights
The unsupported length of walls between cross
walls should be limited to 5/6m
for longer walls, cross supports raised from the
ground level called buttresses should be provided
at spacing not more than 4m.
The height of each storey should not exceed 3.0m
14. Horizontal Bands
Why are Horizontal Bands necessary in Masonry
Building
providing out-of-plane bending resistance to the wall
by forming a rigid horizontal frame with continuity at
the corners
reducing the unsupported vertical height of the wall to
that between the two consecutive bands, like plinth and
lintel
15. There are four types of bands in a typical masonry
building, namely gable band, roof band, lintel band
and plinth band , named after their location in the
building
The lintel band is the most important of all and
needs to be provided in almost all buildings
The gable band is employed only in buildings
with pitched or sloped roofs
22. Types of damage in buildings without vertical bands
Rocking of masonry piers
When the ground shakes, the
inertia force causes the small-
sized masonry wall piers to
disconnect from the masonry
above and below. These masonry
sub-units rock back and forth,
developing contact only at the
opposite diagonals
The rocking of a masonry pier
can crush the masonry at the
corners
23. X-Cracking of Masonry
Piers
The rocking of a masonry pier
can crush the masonry at the
corners. Rocking is possible
when masonry piers are
slender, and when weight of the
structure above is small.
Otherwise, the piers are more
likely to develop diagonal (X-
type)shear cracking (Figure 2c);
this is the most common failure
type in masonry buildings.
24. •Horizontal sliding at sill level
in masonry building
During strong earthquake shaking
, the building may slide just under
the roof, below the lintel band or at
the sill level. Sometimes, the
building may also slide at the
plinth level. The exact location of
sliding depends on numerous
factors including
building weight, the earthquake
-induced inertia force,
the area of openings, and type of
doorframes used.
25. When a wall with an opening
deforms during earthquake shaking
, the shape of the opening distorts
and becomes more like a rhombus
- two opposite corners move away
and the other two come closer.
Under this type of deformation, the
corners that come closer develop
cracks . The cracks are bigger
when the opening sizes are larger
Cracking in building with
no corner reinforcement
26. How Vertical Reinforcement Helps ?
Embedding vertical
reinforcement bars in the edges of
the wall piers and anchoring
them in the foundation at the
bottom and in the roof band at the
top , forces the slender masonry
piers to undergo bending instead of
rocking
Steel bars provided in the
wall masonry all around the
openings restrict these
cracks at the corners
27. Sliding failure mentioned above is rare, even in unconfined masonry buildings.
However, the most common damage, observed after an earthquake, is diagonal X-
cracking of wall piers, and also inclined cracks at the corners of door and window
openings
28. Fig 6: Containment reinforcement scheme
integrated with horizontal bed
reinforcement
Fig 7: Schematic diagram of vertical and horizontal
reinforcement in a masonry building Specification for
vertical ‘containment reinforcement’
29. Normally, the horizontal spacing between two sets of containment reinforcement should
be between 0.75m to 1.25m.
The wires/rods of containment reinforcement must be tied to the steel in the
horizontal band to form a coarse two-dimensional cage holding the masonry in place.
For providing vertical bar in stone masonry a casing pipe is recommended around which
the masonry is built to heights of 600 mm, The pipe is kept loose by rotating it during
masonry construction. Then the casing pipe is raised and the cavity below is filled with
1:2:4 concrete mix and rodded to compact it. The concrete will not only provide the
bond between the bar and the masonry but will also protect the bar from corrosion.