Seismic design is based on authorized engineering procedures, principles and criteria meant to
design or
retrofit structures subject to earthquake exposure. Therefore, a building design which exactly follows seismic code regulations does not guarantee safety against collapse or serious damage. The price of poor seismic design may be enormous. Nevertheless, seismic design has always been a
trial and error process whether it was based on physical laws or on empirical knowledge of the
structural performance of different shapes and materials. destroyed by
1906 earthquake and fire after the
1906 earthquake and fire To practice
seismic design, seismic analysis or seismic evaluation of new and existing civil engineering projects, an
engineer should, normally, pass examination on
Seismic Principles which, in the State of California, include: • Seismic Data and Seismic Design Criteria • Seismic Characteristics of Engineered Systems • Seismic Forces • Seismic Analysis Procedures • Seismic Detailing and Construction Quality Control To build up complex structural systems, seismic design largely uses the same relatively small number of basic structural elements (to say nothing of vibration control devices) as any non-seismic design project. Normally, according to building codes, structures are designed to "withstand" the largest earthquake of a certain probability that is likely to occur at their location. This means the loss of life should be minimized by preventing collapse of the buildings. Seismic design is carried out by understanding the possible
failure modes of a structure and providing the structure with appropriate
strength,
stiffness,
ductility, and
configuration to ensure those modes cannot occur.
Seismic design requirements Seismic design requirements depend on the type of the structure, locality of the project and its authorities which stipulate applicable seismic design codes and criteria. incorporate an innovative seismic performance-based approach. was closed after the
1988 Armenian earthquake. The most significant feature in the SDC design philosophy is a shift from a
force-based assessment of seismic demand to a
displacement-based assessment of demand and capacity. Thus, the newly adopted displacement approach is based on comparing the
elastic displacement demand to the
inelastic displacement capacity of the primary structural components while ensuring a minimum level of inelastic capacity at all potential plastic hinge locations. In addition to the designed structure itself, seismic design requirements may include a
ground stabilization underneath the structure: sometimes, heavily shaken ground breaks up which leads to collapse of the structure sitting upon it. The following topics should be of primary concerns: liquefaction; dynamic lateral earth pressures on retaining walls; seismic slope stability; earthquake-induced settlement.
Nuclear facilities should not jeopardise their safety in case of earthquakes or other hostile external events. Therefore, their seismic design is based on criteria far more stringent than those applying to non-nuclear facilities. The
Fukushima I nuclear accidents and
damage to other nuclear facilities that followed the
2011 Tōhoku earthquake and tsunami have, however, drawn attention to ongoing concerns over
Japanese nuclear seismic design standards and caused many other governments to
re-evaluate their nuclear programs. Doubt has also been expressed over the seismic evaluation and design of certain other plants, including the
Fessenheim Nuclear Power Plant in France.
Failure modes Failure mode is the manner by which an earthquake induced failure is observed. It, generally, describes the way the failure occurs. Though costly and time-consuming, learning from each real earthquake failure remains a routine recipe for advancement in
seismic design methods. Below, some typical modes of earthquake-generated failures are presented. s at earthquakes,
Loma Prieta The lack of
reinforcement coupled with poor
mortar and inadequate roof-to-wall ties can result in substantial damage to an
unreinforced masonry building. Severely cracked or leaning walls are some of the most common earthquake damage. Also hazardous is the damage that may occur between the walls and roof or floor diaphragms. Separation between the framing and the walls can jeopardize the vertical support of roof and floor systems. collapse due to inadequate shear strength at ground level,
Loma Prieta earthquake Soft story effect. Absence of adequate stiffness on the ground level caused damage to this structure. A close examination of the image reveals that the rough board siding, once covered by a
brick veneer, has been completely dismantled from the stud wall. Only the
rigidity of the floor above combined with the support on the two hidden sides by continuous walls, not penetrated with large doors as on the street sides, is preventing full collapse of the structure. during the
1964 Niigata earthquake Soil liquefaction. In the cases where the soil consists of loose granular deposited materials with the tendency to develop excessive hydrostatic pore water pressure of sufficient magnitude and compact,
liquefaction of those loose saturated deposits may result in non-uniform
settlements and tilting of structures. This caused major damage to thousands of buildings in Niigata, Japan during the
1964 earthquake. rock,
2008 Sichuan earthquake Landslide rock fall. A
landslide is a geological phenomenon which includes a wide range of ground movement, including
rock falls. Typically, the action of
gravity is the primary driving force for a landslide to occur though in this case there was another contributing factor which affected the original
slope stability: the landslide required an
earthquake trigger before being released.
Pounding against adjacent building. This is a photograph of the collapsed five-story tower, St. Joseph's Seminary,
Los Altos, California which resulted in one fatality. During
Loma Prieta earthquake, the tower pounded against the independently vibrating adjacent building behind. A possibility of pounding depends on both buildings' lateral displacements which should be accurately estimated and accounted for. At
Northridge earthquake, the Kaiser Permanente concrete frame office building had joints completely shattered, revealing
inadequate confinement steel, which resulted in the second story collapse. In the transverse direction, composite end
shear walls, consisting of two
wythes of brick and a layer of
shotcrete that carried the lateral load, peeled apart because of
inadequate through-ties and failed. • Improper
construction site on a
foothill. • Poor detailing of the
reinforcement (lack of concrete confinement in the columns and at the beam-column joints, inadequate splice length). • Seismically weak
soft story at the first floor. • Long
cantilevers with heavy
dead load.
Sliding off foundations effect of a relatively rigid residential building structure during
1987 Whittier Narrows earthquake. The magnitude 5.9 earthquake pounded the Garvey West Apartment building in Monterey Park, California and shifted its
superstructure about 10 inches to the east on its foundation. If a superstructure is not mounted on a
base isolation system, its shifting on the basement should be prevented. to buckle,
Northridge.
Reinforced concrete column burst at
Northridge earthquake due to
insufficient shear reinforcement mode which allows main reinforcement to
buckle outwards. The deck unseated at the
hinge and failed in shear. As a result, the La Cienega-Venice
underpass section of the 10 Freeway collapsed.
Loma Prieta earthquake: side view of reinforced concrete
support-columns failure which triggered
the upper deck collapse onto the lower deck of the two-level Cypress viaduct of Interstate Highway 880, Oakland, CA. due to ground movement,
Loma Prieta Retaining wall failure at
Loma Prieta earthquake in Santa Cruz Mountains area: prominent northwest-trending extensional cracks up to 12 cm (4.7 in) wide in the concrete
spillway to Austrian Dam, the north
abutment. Ground shaking triggered
soil liquefaction in a subsurface layer of
sand, producing differential lateral and vertical movement in an overlying
carapace of unliquefied sand and
silt. This
mode of ground failure, termed
lateral spreading, is a principal cause of liquefaction-related earthquake damage. Severely damaged building of Agriculture Development Bank of China after
2008 Sichuan earthquake: most of the
beams and pier columns are sheared. Large diagonal cracks in masonry and veneer are due to in-plane loads while abrupt
settlement of the right end of the building should be attributed to a
landfill which may be hazardous even without any earthquake. strikes
Ao Nang Twofold tsunami impact:
sea waves hydraulic
pressure and
inundation. Thus,
the Indian Ocean earthquake of December 26, 2004, with the
epicenter off the west coast of
Sumatra, Indonesia, triggered a series of devastating tsunamis, killing more than 230,000 people in eleven countries by
inundating surrounding coastal communities with huge waves up to 30 meters (100 feet) high. == Earthquake-resistant construction ==