Earthquake Resistance planning

Elementary Seismology &
Earthquake Resistance
Building Planning
Sumanta Das
SRM University, Kattankulathur

Seismology
The term ‘Seismology’ is derived from Greek word
Seismo, which means earthquake and logos means
science; hence the Seismology is Science of
Earthquakes
Seismology can be defined in two ways:
1. The science of earthquakes and the physics of the
earth’s interior
2. The science of elastic wave (seismic waves)

CONTINENTAL
DRIFT

Prepared by CT.Lakshmanan

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1) Crust: thikness~5 to 40km
Light materials (e.g basalts and granites)
2) Mantle: thickness ~2900km
Has ability to flow outer core materials
3) Outer Core: thickness ~2200km
In Liquid form
4) Inner Core: radius ~1290km
solid and consists of heavy metals
(e.g., nickel and iron)
INSIDE THE EARTH

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Local
Convective
Currents in the Mantle
Major seven Tectonic Plates on the Earth’s surface

The convective flows of Mantle material cause the Crust and some portion of
the Mantle, to slide on the hot molten outer core. This sliding of Earth’s mass
takes place in pieces called Tectonic Plates.

Source: from internet

Fault
A fault is nothing but a crack or weak zone inside the Earth. When two blocks of rock
or two plates rub against each other along a fault, they don’t just slide smoothly.
As the tectonic forces continue to prevail, the plate margins exhibit deformation as
seen in terms of bending, compression, tension and friction. The rocks eventually
break giving rise to an earthquake, because of building of stresses beyond the
limiting elastic strength of the rock.


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 There are three types of inter-plate interactions are the and
boundaries

1) convergent

2) divergent

3) transform

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 How the ground shakes?

 Large strain energy released during an earthquake travels as seismic waves in
all directions through the Earth’s layers, reflecting and refracting at each
interface.
These waves are of two types

Body waves
1. P-waves
2. S-waves

Surface waves

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Arrival of Seismic Waves at a Site

Motions caused by Body and Surface Waves

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BASIC TERMINOLOGY
Focus: The point on the fault where slip
starts.
Epicenter: The point vertically above this
on
the surface of the Earth.
Focal Depth: The depth of focus from the
epicenter.
 Epicentral distance: Distance from
epicenter to any point of interest
Aftershocks and Foreshocks :
Those occurring before the big one are
called

Magnitude Vs Intensity
The magnitude of an earthquake is
determined instrumentally and is more
objective measure of its size
Intensity of an earthquake is a subjective
parameter based on assessment of visible
effects. It depends on factors other than
the actual size of the earthquake

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MAGNITUDE :

INTENSITY

Magnitude is a quantitative measure

Intensity is an indicator of the severity

of the actual size of the earthquake.

of shaking generated at a given location

Measured by Richter Scale

 Measured by Mercalli scale

Denoted by M(number) i.e. M8 or

severity of shaking is much higher near the

M7.7

epicenter than farther away.

Same at every places like M7

Intensity is varies at each and every place.

EARTHQUAKE MAGNITUDE
CLASS
USGS

IMD

M>8

Great

Very great

7 - 7.9

Major

Great

6 - 6.9

Strong

Moderate

5 - 5.9

Moderate

Moderate

4 - 4.9

Light

Slight

3 - 3.9

Minor

Slight

M<3

Micro
earthquake

GLOBAL EARTHQUAKE
OCCURRENCE
Magnitude

Annual Average No.

M >8

2

7 - 7.9

20

6 - 6.9

100

5 - 5.9

3000

4 - 4.9

15,000

3 - 3.9

>100,000


IS 1893:2002
More than 60 % area is
earthquake prone.
Zone V
%

12

Zone IV
Zone III
Fig. courtesy: nicee

18 %
26 %

Zone II
%


44

The Vulnerability Profile - India









59% of land mass prone to earthquakes
40 million hectares (8%) of landmass prone to floods
8000 Km long coastline with two cyclone seasons
Hilly regions vulnerable to
avalanches/landslides/Hailstorms/cloudburst
68% of the total area susceptible to drought
Different types of manmade Hazards
Tsunami threat
1 million houses damaged annually + human, economic,
social and other losses

Hazard, vulnerability & disaster

Disaster = F (Hazard, Vulnerability)

Ingredients of Risk
HxV-C=R
Hazard x vulnerability – capacity = risk
H - potential threat to humans and their welfare
V - exposure and susceptibility to loss of life or dignity
C - available and potential resources
R - probability of disaster occurrence

-

Capacity “resources, means and strengths which exist in
households and communities and which enable them to cope with,
withstand, prepare for, prevent, mitigate or quickly recover from a
disaster”

Earthquake Do Not Kill People

Improperly Designed Structures Do!

• The structure is to resist minor earthquake without
damage.
• The structure is to resist moderate and frequently
occurring earthquakes without any structural
damage, but minor cracks are permissible during
earthquakes
• The structure shouldn’t collapse under severe
earthquake.

Planning Parameters for EQRB
• Planning should be based on seismic IS codes i.e. IS
1893-2002, IS 13920-1993
• The base soil should be strong and compacted.
• The zone should be free from seismological hazards.
• Important heavy structures like dams, nuclear power plant
etc. should be planned for higher level of earthquake
protection.
• The weight of building should be as less as possible.
• Building height and width ratio should be maintained.
• Reinforced structure should be planned.
• All parts of buildings like columns, beams, roofs should be
well connected properly

• Shear walls, ductility of buildings with greater quality
should be provided for more safety.
• Avoid corners, soft stories at ground floor, short column.
• Good materials, modern engineering technologies,
skilled engineers and labors, fund and construction
methods should be maintained.


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What are the seismic effect on structures?

1.

Inertia force in structures:
Earthquake causes shaking of the
ground. So a building resting on it will
experience motion at its base. From
Newton’s First Law of Motion, even
though the base of the building moves
with the ground, the roof has a tendency
to stay in its original position. But since

Effect of Inertia in a building
when
shaken at its base

the walls and columns are connected to
it, they drag the roof along with them.

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Effect of Inertia in a building when
shaken at its base

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Modes and patterns of failure of Buildings
(1) Soft/weak stories

A soft or weak storey is created when the lateral stiffness and/or
strength of a storey is markedly more flexible than the floors
above and below.

Soft story

This often occurs at the ground
floor when it is left open for
parking, a shop front, or other
reasons.
Most of the deformation is
concentrates at this level and
results in large rotation demand
in columns.

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A typical soft storey
collapse

In this case, after the
first storey failed, this
added force of impact at
each

floor

subsequent
collapse.

Typical soft storey collapse in Bhuj

caused
stories

to

Earthquake Design Philosophy


IMPORTANT CONSIDERATIONS TO MAKE
A BUILDING EARTHQUAKE RESISTANT
1. Configuration
2. Ductility
3. Quality control
4. Base Isolation


1. Configuration

A terminally ill patient , however
effective the medication, may
eventually die.
Similarly, a badly configured building
Cannot be engineered for an improved
performance beyond a certain limit.


Regular Configuration
• Regular configuration is seismically ideal. These
configurations have low heights to base ratio,
symmetrical plane, uniform section and elevation
and thus have balanced resistance.


These configurations
would have maximum
torsional resistance due
to location of shear walls
and bracings. Uniform
floor heights, short spans
and direct load path play
a significant role in
seismic resistance of the
building.

Irregular Configuration
Buildings with irregular configuration

Buildings with abrupt changes in
lateral resistance
Buildings with abrupt changes in
lateral stiffness

Re-entrant corner


Out of plane Offsets
Shear
Wall
Out-of-Plane Offset
in Shear Wall

Non-parallel system

Shear
walls

ELEVATION IRREGULARITIES

1) Soft-Storey/Pan-caked

2) Set-backs


3) Connections

ELEVATION IRREGULARITIES

4) Pounding

5) Breaks in
Columns
or Beams

6) Staggered
Levels


7) In-fills

Right or Wrong…?


Ductility
Let us first understand how different materials behave.
Consider white chalk used to write on blackboards and steel pins with solid
heads used to hold sheets of paper together. Yes… a chalk breaks easily!!
On the contrary, a steel pin allows it to be bent back-and-forth. Engineers define
the property that allows steel pins to bend back-and-forth by large amounts, as
ductility; chalk is a brittle material.


The currently adopted performance criteria in the earthquake codes
are the following:
i. The structure should resist moderate intensity of earthquake
shaking without structural damage.
ii. The structure should be able to resist exceptionally large intensity
of earthquake shaking without collapse.


The strength of brittle construction
materials, like masonry and
concrete, is highly sensitive to the
1. quality of construction materials
2. workmanship
3. supervision
4. construction methods

Quality control
special care is needed in construction to ensure
that the elements meant to be ductile are indeed
provided with features that give adequate
ductility.
Thus, strict adherence to prescribed standards of
construction materials and construction
processes is essential in assuring an earthquakeresistant building.

Elements of good quality control
1.Regular testing of construction
materials at qualified laboratories (at
site or away)
2. Periodic training of workmen at
professional training houses, and
3. On-site evaluation of the technical
work

IS CODES
IS 1893 (Part I), 2002, Indian Standard Criteria for Earthquake Resistant Design
of Structures (5th Revision)
IS 4326, 1993, Indian Standard Code of Practice for Earthquake Resistant
Design and Construction of Buildings (2nd Revision)
IS 13827, 1993, Indian Standard Guidelines for Improving Earthquake
Resistance of Earthen Buildings
IS 13828, 1993, Indian Standard Guidelines for Improving Earthquake
Resistance of Low Strength Masonry Buildings
IS 13920, 1993, Indian Standard Code of Practice for Ductile Detailing of
Reinforced Concrete Structures Subjected to Seismic Forces


Base isolators


While Hazards Are Inevitable, Each Hazard Need Not Convert
Into A Disaster… As What Comes In Between Is
The Culture of Safety And Prevention
Let us Work Together to Build a Culture of Prevention !

Earthquake Resistance planning

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