Disaster Resistant Buildings
EARTHQUAKES
RESISTANT BUILDINGS
An earthquake
is a sudden, rapid shaking of the earth surface caused by the breaking and
shifting of rocks beneath. During earthquake, ground motion occurs in a random
fashion in all directions radiating from a point within earth crust, called
epicentre. It causes vibrations of structures and induce inertia forces on
them. As a result structure may collapse resulting into loss of property and
lives. Earthquakes
do not kill people,
vulnerable buildings do so. Hence there is need of designing earthquake
resistant buildings, especially in the earthquake prone areas.
TYPES OF
EARTHQUAKES
Depending
upon the possible causes, the earthquakes may be classified as:
1. Natural
earthquake
2. Earthquakes
due to induced activities.
Natural
Earthquakes
Natural
earthquakes may be due to
(i) active faults
(ii) movement of tectonic plates or
(iii) due to volcanic eruptions.
In earth’s
crust there are some faults which are not yet settled. The displacement of
rocks along faults cause earthquake. Tectonic means large scale process
affecting the structure of the earth crust. This process causes gradual
movement of material within the crust of earth. Sometimes it shakes the earth
crust. Volcano is a mountain or hill having a crater through which lava, rock
fragments, hot vapour and gas are or have been erupted from the earthscrust. Occasionally the volcanoes become active and
create earthquake near the mountain crater.
Earthquakes
due to Induced Activities
These are
caused by vibrations induced by atomic explosions and collapse of ground due to
faulty mining.
TERMINOLOGY
1.
Focus: The
point on the fault where slip starts is the focus. It is also known as
hypocentre
2.
Epicentre: The point vertically above the focus on the surface of the earth
is the epicentre.
3. Focal
Depth: The
depth of focus from the epicentre is called the focal depth.
4. Epicentral Distance: Distance from epicentre to any
point of interest on the surface of earth is called epicentral distance.
MAGNITUDE
AND INTENSITY
Magnitude is a
quantitative measure of the actual size of the earthquake. Professor Charles
Richter proposed the scale of magnitude that goes from 0 to 9. It is a
geometric scale. Now this scale is known as Richter scale. It is obtained from
the seismograph. It depends on waveform amplitude on epicentral distance.
It is denoted by letter M followed by the number. An increase in magnitude by 1
implies 10
times higher waveform
amplitude and about 31 times higher energy released. Thus energy released in M6
and M5 earthquake have the ratio 31, and M8 to M5 have the ratio 31 × 31 × 31.
There are other magnitude scales, like the Body Wave Magnitude, Surface Wave
Magnitude and Wave Energy Magnitude. Intensity is a qualitative measure of the
actual shaking at a location during an earthquake. Hence
for the same
earthquake, it has different values at different places, highest value being at
epicentre. This is a linear scale. It is assigned as Roman Capital Numbers from
I to XII. Intensity depends upon
1. Amount of
source energy released
2. Distance
between the source and the place of interest
3.
Geographical features of the media of travel and importantly on the type of
structure. Modified Mercalli Intensity
(MMI) scale is commonly used to express the intensity.
MMI scale
is as given below:
I. Very
slight, felt only by instruments
II. Felt by
people resting
III. Felt by
passing traffic
IV.
Furniture’s and windows rattle
V. Can be felt
outdoors, clocks stop, doors swing
VI.
Furniture’s move about, cracks appear in walls
VII. People
knocked over, masonry cracks and falls
VIII. Chimneys
and monuments fall, buildings move on foundations
IX. Heavy
damage to buildings, large cracks open on ground
X. Most
buildings destroyed, landslides occur, water thrown out of lakes
XI.
Catastrophic, railway lines badly bent
XII. Utter
catastrophic, no building is left standing.