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Transcript of REAKT-D7.3
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Project number: 282862
Project name: Strategies and tools for Real Time Earthquake RiskReduction
Project acronym: REAKT
Theme: ENV.2011.1.3.1-1
Towards real-time earthquake risk reduction
Start date: 01.09.2011
End date: 31.12.2013 (24 months)
Deliverable: D 7.3 Final report for Feasibility studies on real-timerisk mitigation in the SINES Industrial Complex,Portugal
Version: Final
Responsible partner: IST
Month due: 36 Month delivered: 40
Primary author: Carlos Sousa Oliveira (IST) 23.12.2014_
Date
Reviewer: Carlo G. Lai (EUCENTRE) 25/09/2014
Date
Authorised: Paolo Gasparini (AMRA) 29.12.2014
Date
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Dissemination Level
PU Public X
PPRestricted to other programme participants (including the CommissionServices)
RERestricted to a group specified by the consortium (including the
Commission Services)CO Confidential, only for members of the consortium (including the
Commission Services)
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Acknowledgement
The research leading to these results has received funding from the European
Community’s Seventh Framework Programme [FP7/2007-2013] under grant
agreement n° 282862.
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INDEX
1. Introduction 5
2. The Sines Industrial Complex 5
2.1. The ZILS (Zona Industrial e Logística de Sines). Industrial & LogisticsPlatform 5
3. Geotechnical characterization 10
4. Risk assessment 11
4.1. QuakeIST seismic simulator. General description 11
4.2. QuakeIST® seismic simulator. Scenarios 14
4.3. Dependencies and interdependencies 15
5. Seismological context and Early warning developments 17
5.1. Early warning developments 18
5.1.1 Epicenters in the SW Iberia 19
5.1.2 Epicenter in the Lower Tagus Valley Region 21
5.1.3 Other early warning developments 22
6. Earthquake early warning survey 24
7. Cost-benefit preliminary analysis 27
References 29
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1. Introduction
The Industrial Complex of Sines (Portugal) with more than 13 km2, is one of the largest
in Europe, housing a significant number of National (Portuguese) and European Critical
Infrastructures. Located next to the Atlantic Coast, at about 180 km from two major
seismogenic sources (the Gorringe Bank and the Marquês de Pombal Fault) both ableto generate a 8.5 to 9 magnitude earthquake, leading to Peak Ground Accelerations of
about 0.20 g to 0.24 g in stiff rock soils, with the possibility of 0.4 g to 0.5 g in soft soils.
In this area, several major industries and services are present, namely a thermal power
generation plant, concrete, chemical and cement production plants, fuel refinery,
dangerous materials and fuel parks, mobile communications, pipelines and many other
critical infrastructures, interacting in a complex physical and functional dependency so,
prone to trigger chain reactions amplifying and propagating disastrous effects. Within a
5 km distance, a population of about 50.000 persons is present, with schools, hospitals,
and many other sensible targets.
Already identified as a risky zone, during the establishment of the National and
European Critical Infrastructures Protection Projects, the Sines Industrial Complex
constitutes an optimum feasibility case study in the field of Seismic Early-Warning. It is
no coincidence that several national and international major stake-holders have already
expressed their interest in this subject, and have already showed their strong
willingness in participating in this Project.
2. The Sines Industrial Complex
The exploitation of the port of Sines started in 1973. Sines assumed an important
geographical position in the world, being a privileged axis at the crossroads of maritime
routes due to its deep-sea water port, combined with good conditions for port
expansion and secured direct access to railway and road networks.
Last year, Sines handled some 25.8 million tonnes of cargo and almost 447,500
twenty-foot equivalent units (TEU). Liquid bulk cargo traffic amounted to 16.2 million
tonnes. (http://shipping.seenews.com/, June 2013).
The expansion of the Panama Canal in 2014, with a direct link from the Pacific to
Atlantic for larger ships, may lead to an increased flow of trade between the Pacific
basin, both coasts of North America, the Mercosur and Europe. Ports like Sines will be
strategic for Europe (Moreira, P.J.P, 2013).
2.1. The ZILS (Zona Industrial e Logística de Sines). Industrial &
Logistics Platform
In which concerns for Sines in terms of Industrial and logistic platform (Figure 1a) and
b)), provided the integrated development of the entire region and emerged on the
concentration of diversified industries and industrial facilities.
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Figure 1a: Plan view of Sines and main infrastructures considered in this study. GIS platform.
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Figure 1b: Plan view of Sines and main partners involved in this study.
Some of the main infrastructures of the harbour are listed and briefly described below:
Sines container terminal “Terminal XX” - the Sines container terminal, called Terminal
XXI, started its operations in 2004 and is the largest container terminal in Portugal.
Figure 2: Sines container terminal “Terminal XX”
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Figure 3: Three-dimensional scheme of the intermodal platform at the container terminal
(Garcia, P.R., 2003)
Sines Petrochemical Complex (REPSOL) - mainly destined for export olefins and
polyolefins. The Port of Sines has a terminal dedicated to petrochemical products.
Figure 4: REPSOL Sines petrochemical complex(Source: http://www.repsol.com/pt)
Sines Refinery (Galp) - diesel production. It is constituted by a number of processing
units spread across two plants, known as Manufacturing I and Manufacturing II. It has a
large storage area with a capacity of approximately 3 million cubic meters for crude oil,
fuels and other final products and intermediate product.
The Sines refined products are: gasoline; diesel; LPG (liquefied petroleum gas); fuel
oil; naphtha (used in the petrochemical industry to produce polymers from which
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plastic, fibers for textiles and even bubble gum is produced); jet fuel (fuel for airplanes);
bitumen (for asphalt and insulate) and sulphur (for pharmaceutical products, farming
and pulp whitening).
Needs: road and sea transport for filling and dispatching every products. Reception of
crude ships
Figure 5: Sines refinery (Source: http://www.galpenergia.com)
Figure 6: The manufacturing I produce gases, gasolines, aviation fuel, diesel and fuel oil
Figure 7: The manufacturing II has several processing units, namely a vacuum distillation and a
visbreaker
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Liquefied Natural Gas (LNG) (REN Atlântico) - The LNG terminal consists of a docking
station with a discharge capacity of 40,000 cubic meters to 165,000 cubic meters with
an average discharge time of 20 hours, two storage tanks each having a capacity of
115,000 cubic meters and five open rack vaporizers for regasification. Storage may
reach 390,000 m3 of liquefied gas.
Figure 8: Sines Liquefied Natural Gas (LNG) (Source: http://www.ren.pt)
3. Geotechnical Characterization
“In geological terms, it is characterized by arenaceous formations in various states of
alteration and covered with various land fill materials. The soil is of a poor grade. The
original soil has been greatly altered and is practically all paved. Mainly it is made oflandfill materials, associated with buildings and roads. As a consequence, these are
zones that have been rendered impermeable to a considerable degree, of no
agricultural or ecological value. The hydro graphic network of the project area is made
of small watercourses that drain directly into the ocean. The most important in the
proximity of the project area are Ribeira das Caraminheiras, on the north, and Ribeira
da Junqueira, on the south, both of which display torrential flow in open channels. No
watercourse is identified in the area of the refinery.”
http://www.galpenergia.com/EN/sustainability/corporate-
responsibility/environment/Documents/EN-RNT_ProjConvesao_RS.pdf
The soil map settled according to the Eurocode 8 classification is shown in Figure 9
and is the input to the earthquake scenario simulator - QuakeIST®. The classification
was based on a preliminary analysis of a geotechnical map from LNEC (1974) and the
geological map from Direcção Geral de Geologia e Minas (1986). Further studies in
this area are needed for a refined analysis.
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Figure 9: Soil classification.
4. Risk assessment
Earthquake simulators developed until now show direct physical damage in terms of
victims, buildings, essential facilities and transportation systems, without including
estimations of indirect losses or propagated effects (functional interdependencies).
The QuakeIST® is an integrated simulator developed by the Instituto Superior Técnico,
and used by the REAKT project to obtain disaster scenarios affecting large scale
systems and their interdependencies.
Simulation can test different sets of decisions for the same disaster scenario to find the
optimal solution for restoration without wasting time and money; finally it can help to
develop a strategy that can increase the resiliency of the critical infrastructures to an
urban area.
4.1. QuakeIST seismic simulator. General description
The QuakeIST® simulator is an integrated earthquake simulator, developed by IST and
written in C++, oriented to risk calculations and damage propagations; and opens up
new territory for earthquake science and engineering with the goal of reducing the
potential for loss of life and property. QuakeIST® using data stored in GIS environment
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can handle different ground motion scenarios provided by the user and compute a
number of output variables corresponding to the existing data under analysis.
The QuakeIST currently has the following characteristics:
i) Users can upload their own hazard, vulnerability and exposure models;
ii) Different types of assets can be modelled (e.g. buildings, lifelines,
population);
iii) Modelling of the cascade effects (disruption index) is considered;
iv) It can be used on a single processor laptop, as well as on a cloud GIS
computing infrastructure (QuantumGIS, etc.)
The project test area (Industrial Complex of Sines) with urban and industrial occupation
constitutes an optimum feasibility case study in the field of Seismic Early-Warning and
contains infrastructures that represent an actual interdependent system containing
enough interconnections for research on multiple infrastructure interdependencies.
In Sines test cases, we considered the following selected buildings, infrastructures and
elements:
- Buildings- Power transformers- Ng pipelines (ng - natural gas)- Water pipes- Port facilities
Each theme (infrastructure and so on) was obtained from the different stakeholders, in
different formats and units. An extensive data treatment was performed in order to
homogenise the information and introduced in the GIS platform and QuakeIST
simulator. A geometrical and mechanical property of each element of the infrastructure
was used to set typologies and corresponding vulnerability functions.
Each type of a structure and infrastructures has its own structural dynamics response
characteristics and hence a particular structural analysis is needed. The literature
review has addressed the issue of vulnerability or fragility relations for each component
subjected to ground shaking. In this step we want to assess the infrastructure
vulnerability level (Table 1).
Table 1. Elements at risk and procedure for vulnerability analysis
Element at risk Methodology Intensity
parameter
Buildings Giovinazzi & LagomarsinoMacroseismic method
EMS98
Power transformers REAKT WP5 PGA
Gas pipelines HAZUS, ALA PGV
Water pipes HAZUS, ALA PGV
In this earthquake loss estimation study, the simplified method for water systemnetwork performance evaluation applies to a distribution pipe network (HAZUS, 2007).
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Material K1 K2 K3
Aço 0.3 0.0001 2.25
Betão Armado 1 0.0001 2.25
Fibrocimento 1 0.0001 2.25
Ferro fundido dúctil 1 0.0001 2.25
FV 0.3 0.0001 2.25
Hidronil 0.3 0.0001 2.25
Não conhecido 0.3 0.0001 2.25
Polietileno de alta densidade 0.3 0.0001 2.25
Poliester reforçado a fibra de vidro 0.3 0.0001 2.25
PVC (Policloreto de vinilo) 0.3 0.0001 2.25
INX 0.3 0.0001 2.25
Damage algorithms for water pipes:
Repair Rate (repairs/km) =K1 x K2 x PGV(K3) [O'Rourke and Ayala (1993)]
Note that the diameter of pipe is not considered to be a factor. For ductile pipelines
(steel, ductile iron and PVC), the above relation is multiplied by 0.3 (i.e., ductile
pipelines have 30% of the vulnerability of brittle pipelines).
Therefore, due to PGV, the estimated number of leaks is 80% x Ʃ nr. Repairs (= RR x
length), and the estimated number of breaks is 20% x Ʃ nr. Repairs.
Acceptable damage rate evaluation:
According to ALA (2001), an acceptable damage rate should be about 0.1 to 0.2
breaks per km. In Repair rates means 0.02 to 0.04.
Authors (Grigoriu et al.) suggest that a break rate of 0.02/km corresponds to about
Intensity VII, and a break rate of 0.10/km corresponds to about Intensity VIII.
For the gas system elements the damage algorithm for gas pipes is:
Repair Rate (repairs/km) =K1 x 0.002416 x PGV [ALA (2001)]
Material K1
Welded steel 0.15
PVC 0.50
Data on location and material were collected and entered into a GIS database,
providing a powerful basis for evaluating earthquakes effects on lifelines, as well as the
consequences of these interactions on communities.
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4.2. QuakeIST ® seismic simulator. Scenarios
One earthquake scenario, 1755 earthquake, was used for simulation of damage and
serviceability of the main elements under study. As an example, we show the gas and
water networks results. For detailing of the ground motion attenuation (GMPE) used
and conversions from/to PGA/PGV/EMS-98 Intensity, soil influence, etc. (Mota de Sáet al., 2014).
Scenario 1: 1755 earthquake, M8.7
Figure 10: Peak ground motion (PGA) obtained for 1755 earthquake scenario (left) and
intensities (EMS-98) (right).
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Figure 11: Repair rates for gas and water networks under 1755 scenario.
The visualization of earthquake impacts which are predicted by such simulation
contributes to make recognition of earthquake disaster among population and urban
services or functions, but also the improvement of the engineering ability of local
government officials who are in charge of promoting earthquake disaster mitigation.
4.3. Dependencies and interdependencies
Since ports are indispensable nodes of supply chains involving many strategicstakeholders and activities interacting with each other, the main focus of IST research
is to provide a conceptual framework integrating the organizational relationships
between supply chain and port stakeholders.
Lifeline systems are interdependent, primarily by virtue of physical proximity and
operational interaction. The disruption or destruction to one infrastructural component
can rapidly cascade into damage to surrounding components, with system-wide
consequences as health, safety, security, economic or social well-being of people.
The earthquake, the aftershocks as well as the tsunami that can be generated can
exacerbate disasters. Damage to lifelines and industrial facilities take off line
immediately following an earthquake. And many of these remain off line from several
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months. These outages have a critical effect on region and national businesses and
overall quality of life.
In Sines cases, raw materials, suppliers, packaging, and shipping services are located
in the same region damaged by an earthquake and also not functioning. Thus, the
operation of modern industrial societies is highly interdependent and the success of aregion in carrying out business and industrial operations can be rapidly eroded by the
failure of a few key services or lifelines.
For a business to operate, it needs to be in a community that is functional following a
large earthquake. However, the damage to housing, schools, hospitals, commercial
structures, factories and infrastructure systems resulted in a wide spread economic and
social disruption.
Part of the overall aim of REAKT is to include in the damage scenarios developed by
QuakeIST®, the concept of Disruption Index (Oliveira et al., 2012; Ferreira, 2012;
Ferreira et al., 2013) and apply it to Sines for different levels of seismic action.
To develop the model, it remains essential to identify the system and their components
as well as the main dependencies and interdependencies. The Industrial disruption
index is based on a methodology developed by (Ferreira, 2012, Oliveira et al., 2012
and Ferreira et al., 2014) which intend to measure the urban disruption, quantifying
how a cascade effect contributes to the disruption of urban activities. A review of the
relevant literature and the contact with the Sines stakeholders possibly to draw the
industrial disruption index, identifying the main sources and infrastructures in an
industrial complex.
Figure 12 illustrate the main interdependencies among facilities and their equipments.
Figure 12: Industrial disruption index (IDI) (Ferreira et al., 2014)
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Table 2 refers that Energy depends on the operation of electric facilities and
components (as local transformers) and the functionality of port of Sines (once the coal
arrives by ship).
Table 2: Adjacency matrix (a “macro analysis”)
5. Seismological context and Early warning developments
Sines is located next to the Atlantic Coast, at about 180 km from various major
seismogenic sources (the Gorringe Bank, the Marquês de Pombal, Pereira de Sousa
and São Vicente Faults) capable to generate 8.5 to 9 magnitude earthquakes (Fig. 13).
These sources will generate peak ground accelerations of about 0.3 g to 0.50 g in stiff
rock soils, with the possibility of 0.4 g to 0.65 g in soft soils.
Another source of seismic activity that affects the Sines area is related to the faults
associated with the Lower Tagus Valley. Here the historical catalogue (Stucchi et al.,
2012) do not show values above M>6.5.
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Figure 13: Location of Sines and instrumental seismicity (1961-2013, from IPMA) and location
of the main historical earthquakes of the portuguese mainland and its adjacent margins. GB:
Gorringe Bank; TP: Tagus Plain; TS: Tore Seamount; FP: Ferradura Plain; AB: Ampere Bank;
FF: Ferradura Fault; GqF: Guadalquivir Fault; LTV: Lower Tagus Valley; MPF: Marquês de
Pombal Fault; NF: Nazaré Fault; MF: Messejana Fault; MVF: Moura-Vidigueira Fault; LF: Loulé
Fault; CAF: Cadiz-Alicante Fault. (adapted from Perreira et al., 2013).
The offshore seismic zones are also potentially tsunamigenic sources with great impact
along Atlantic coast south of Lisbon, including Sines. There will be a tsunami early
warning (TEW) of most importance and relevance for the Complex of Sines as well asfor many other low coastal regions. This subject is not addressed in REAKT.
5.1. Early warning developments
Stations that can incorporate the Early Warning Systems (EWS) in continental Portugal
belong to the networks in function (Figure 14). Many of them are not yet fully online.
But, they already can be used to study the feasibility of a EWS, mainly to assess the
possible “lead time” for the case these stations become fully online. There are broad -
band Seismological Stations and strong motion 18-24 bit Stations.
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Figure 14. Seismological Stations in continental Portugal and a cloud of epicentres: dark bluetriangles – IPMA; red triangles – SM, IST; light blue triangles – SM-IPMA. Left - detail stations
location SVI (São Vicente) and PFVI (Vila do Bispo). (courtesy: S. Custódio, 2012).
5.1.1 Epicentres in the SW Iberia
Table 3 shows a group of several earthquakes recorded in the period 2007-2013,
corresponding to the largest magnitudes over the last 10 years and to the ones
recorded with best equipment. These events are all M~2-3, with epicentres in the
southern part of the continental Portugal, the most active area. Two larger events,M>5.5 were also added. The arrival times of P and S waves to several stations were
reported in the EMSC-CSEM catalogue (2014).
Table 3: Earthquakes considered in the current analysis
For the purposes of early warning systems and mitigation, information on the arrival
times of P and S waves to different stations is useful. Data reported in Figure 15 shows
their time difference (S-P), for those stations against epicentral distance (obtained from
Table 3). We plotted the S-P arrival at each station and the S-P1, where P1 is the
arrival time at the station closer to the epicentre, IPMA (2014) Station PFVI (Figure 15),located at the southernmost point of continental Portugal.
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It is clear that if we only consider these times without any time for data treatment and
transmission, with the S-P1 we would increase the lead time in relation to one
calculated from the on-site S-P measurement of 15 sec for sites 200 km away from the
epicentre (Sines) and 22 sec for sites at 270 km (Lisbon). This corresponds to the time
difference between the two lines of Figure 15.
The total lead time without any delay time (the top line in Figure 16) is about 35 sec for
Sines if the detection is made in PFVI, or 38 sec if detection is made at SVI station (at
the São Vicente southwest most location).
Figure 15: Lead time in seconds for epicentres located SW of continental Portugal (Sines is
around 100 km from the southernmost location of continental Portugal where the Station PFVI is
located).
According with recent studies developed by Carranza et al. (2013), based on the
existing seismographic stations of IPMA (2014), the lead time for Sines for an event
with epicentre at about 289 km based on 5, 8 and 10 stations are 25 sec, 16 sec and
12 sec, respectively (Figure 16). Data treatments comprises the automatic analysis of
the accelerograms near the seismic source, leading to an estimation of the magnitude
and epicentral location, allowing the estimation of ground motions amplitude at any site
of interest. This can be done in 4-6 sec, depending on the algorithms. The decision of
issuing a warning will then be automatically made by means of comparing the
estimated values of a ground motion indicator with the threshold values of that indicator
to be defined as a function of the stakeholders needs.
However the above mentioned lead times present large differences that may be
reduced optimizing the location of the different stations, by means of concentrating a
large number of stations closer to the potential epicentre. With the current network
configuration, a minimum number of 10 stations needed to trigger the alert would mean
that Portimão would be within the blind zone that could not be alerted. Only 5 sec
would be available at Faro, 21 sec at Lisbon and 46 sec at the farthest city, Seville
(Spain).
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Figure 16: Lead time in seconds for an epicentre located SW of Continent (289 km from
Sines) (courtesy: M. Carranza et al., 2013)
The numbers presented in Figures 15 and 16 are not totally in agreement with each
other because Figure 16 was made with various epicentre locations closer to São
Vicente than the epicentre considered in Figure 14. Nevertheless, the values presented
in Figure 15 and 16 are quite similar in tendency. The more stations are used in the
computation the higher the reliability of the estimation and, of course, the smaller the
lead time. Perhaps, if stations are organized in a linear array in an L-shape along the
coast line, the gains might be higher.
Similar results were obtained by Pazos et al. (2014) and by Romeu et al. (2014) which,
using different software arrived for Lisbon to a lead time from 20 to 39 sec for two
epicentre locations, 100 and 200 km SW of PFVI Station.
Further studies are being done using only the arrival of the S waves at an advanced
location. This would present higher reliability on the estimations of S waves at Sines.
5.1.2 Epicentre in the Lower Tagus Valley Region
For the epicentres in the Lower Tagus river Valley (LTV) the situation is much different
from the first one. We do not have good information to understand how much lead time
we would have to send alerts to Sines. No event in the LTV zone has occurred in
recent times to allow an exercise similar to the one we did for events with epicentre
southwest of the continental Portugal where large magnitudes are expected.
The distance from LTV seismic sources to Sines vary quite significantly. If we
concentrate only in the faults to the north of Lisbon with an epicentral distance of 110
km, and considering the same model of Figure 15 and not discounting the time for data
treatment and transmission, the on-site S-P would be of just 12 sec, and if we use one
station 50 km ahead of Sines detecting the onset of P waves, the lead time would be
19 sec. For a feasible estimation, which would require more stations, the final lead time
for EEW would probably be very little.
For other offshore epicentral locations, at smaller distances (< 50 km) from Sines, the
lead time for EEW would result solely from on-site S-P arrivals and could be as much
as the epicentral distance would permit.
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5.1.3 Other early warning developments
Normally we look at times until the arrival of S-waves as the onset of important shaking
whose effects should be avoided or minimized. However, a structure takes some time
to respond to the input ground motion, depending essentially on the ratio of
“predominant” frequency and frequency of structure and on structural damping. In asimplified way and in case of a building (control installations) what we want is to launch
actions before the building attains a certain level of danger to the people inside. Actions
may be to escape from the building, to move to some shelter or safe place inside, to
proceed to open doors to the outside, etc. In other words, besides other considerations
dealing for instance with mobility under strong shaking, or at dark, or walk through
toppled objects, we are also interested to know how much time we may have since the
onset of S-waves to the moment the building attains the structural damage levels D2 to
D4 degree (Grünthal, 1998) in a scale of 5 levels. It is important to notice that the
effects of seismic actions in industrial equipment should be given not only in terms of
structural damage but also in terms of content release that may be activated during or
after the shaking (fire, leakage, toxic dispersion and so on) (Salzano et al., 2009).
Damages and losses of certain types of containments may be more important than the
direct damages inflicted. Also the effect of interdependences may be crucial to the
functionality of other equipment and facilities. In these cases short lead times might be
sufficient to block the cascade effect caused by interdependences or reduce factors
that contribute to leakage of toxic or dangerous products.
We present here the first steps to compute the time from the onset of S-wave to attain
various levels of structural performance, this is the time it takes for a structure to reach
several degrees of response related with the level of damage that the structure is
suffering. (Oliveira et al., 2014). First of all a collection of strong ground motionsrecords were selected to perform this analysis. Only earthquakes with M>6 and
especially M>8 where used: Izmit 1999 and Duzce 1999 (nearby) and Chile 2010 (far
away). We performed linear analysis for a group of single degree of freedom systems
with periods varying from 0.2 to 2.0 sec and a damping ratio of 1%, and non-linear
analysis for a Takeda hysteretic response using the commercial program CSI-
SAP2000®, (CSI, 2008) representing the most common building structures existing in
southern Portugal. This analysis is important to study not only the buildings that house
the control facilities.
We evaluated for these structures the time tDi for the structure to attain the level of
response capable of inducing D2 to D4 damage levels. The preliminary results indicate
that for near-field earthquakes the instant at which the PGA takes place is very close to
the instant of the maximum of the response, regardless of the period of the oscillator,
Figure 17. Usually, depending on the magnitude, the time from the onset of S-wave is
only a few seconds. This time enlarges for larger magnitudes, as it can be spotted in
Figure 18.
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a)
b)
Figure 17. Time from the onset of S-wave up to the attainment of various levels of structural
performance: a) time to maximum response in linear case (Vinas del Mar, Chile); b) time to tD2,
tD3 and tD4 for nonlinear case for building typologies constructed in the period 1960-1986
(Chile earthquake 2010). (T(s) – period; t(s) – onset time; Max past and Max prior PGA
represent the times to reach maximum values attained immediately past and prior to PGA).
Even though these preliminary results show that it might be possible to gain a few more
seconds from the onset of the S-wave, especially for the very large magnitudes, many
more examples should be carried out both using a larger selection of ground motion
records, and extending the type of structures under analysis.
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a)
b)
Figure 18. Time from the onset of S-wave to attain various levels of structural performance as a
function of the magnitude of event: a) time to maximum response in linear case (March 11,
2011 Tohoku records were added) ; b) time to tD2, tD3 and tD4 for nonlinear case for building
typologies constructed in the period 1960-1986. (Note: the magnitude scale cannot reach so
large values).
6. Earthquake early warning survey
A survey was developed and sent to stakeholders to test these assumptions andexplore the views of potential users in the following issues, demonstrating how variousstakeholders are positioning themselves in relation to early warning:
- how these stakeholders might use warnings of 12 and 25 seconds duration, theperceived benefits, costs and challenges in use of an earthquake early warningsystem;
0
5
10
15
20
5 6 7 8 9 10
t ( s )
Magnitude(Mw)
PeakAccelerationArrival
- starting from S-Wave
arrival
0.00
2.00
4.00
6.00
8.00
10.00
12.00
5 6 7 8 9 10 11
typology
1960/1986
Magnitude (Mw)
tD2(s)
tD3(s)
tD4(s)
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- determine what benefits the early warning system can realistically provide, andwhat is outside its capacities;
- analyse the ratio between lead time (early warning) and time necessary toperform some actions;
- understand people behaviour after they receive a warning? — particularly howthey prioritize different risks;
- identify actions that might be taken with 12 seconds warning and 25 seconds;- analyze the importance of false alarms, errors and missed events;- what do they think is the best balance between lead time and reliability, for their
equipment.
A lack of understanding of the uncertainty of estimations led some final users and thepublic in general to interpret some predictions that did not take place as wrongpredictions, and to believe that estimations could no longer be trusted. Statementssuch as "there is a 20 per cent chance that rainfall will be above the inter-annual mean"
present information in an unfamiliar language.
It is important to report, communicate and have an appropriate and effective interactionamong the main actors of the early warning process, such as the scientific community,stakeholders and decision makers. In addition, the scientific community messageshould communicate the level of uncertainty and the possibility of induced costs oftaking action after a warning that later is verified to be a false alarm. This requires themessage from the scientists to the final users to be stated in simple language so as tobe understood by those who receive it.
During the REAKT project a survey on user acceptability was conducted (March-June2014) to identify how the organizations might use warnings of 12 and 25 seconds, the
perceived benefits, and assess the factors that may influence organizationalacceptance and use of such a system.
A summary of the survey results is presented below:
1. Do your facilities were hit by some disaster (e.g., fire, floods, tornadoes, etc.) and didNOT receive any warning of their occurrence?
Yes: 0; No: 100%
2. How satisfied are you with the available warning systems on your installations?
Don’t know Very satisfied Satisfied Poor satisfied Not satisfied
Central phone 60% 40%
Sirens (light) 40% 60%
Sirens (sound) 40% 60%
Loudspeakers 40% 40% 20%
Radio/TV 100%
SMS 100%
Email 40% 40% 20%
Others 40%
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3. Do you consider early warning systems for fires, release of toxic substances, etc. asa strategy to effectively reduce the risk and vulnerability of your facilities/installationsand community?
Yes: 100%; No: 0
4. Knowing that your installation can be hit by strong earthquakes (and possibletsunamis), do you consider of utmost importance to install a warning system forearthquakes and tsunamis in your industrial facility?
Yes: 83%; No: 17%
5. Consider the occurrence of an earthquake and its vibration. Do you think that 12
seconds (with probability of success of 95%) is sufficient to take effective actions thatreduce the risk of fire/explosion/spill/other (e.g. equipment shutdown) and allow preparing an appropriate response?
Yes: 17%; No: 83%
6. Consider the occurrence of an earthquake and its vibration. Do you think that 25seconds (with probability of success of 70%) is sufficient to take effective actions thatreduce the risk of fire/explosion/spill/other (e.g. equipment shutdown) and allow
preparing an appropriate response?
Yes: 17%; No: 83%
7. What is the importance of a False Alarm (vibration) to your facility?
Don’tknow
Veryimportant
IndifferentLowimportant
Notimportant
In terms of security 33% 33% 17% 17%
In terms of costs (to restart
the system) 67% 23%
8. List the equipments that could benefit most from early warning system (vibration).
Valves connecting pipes and storage tanks as well as pressurized vessels containingliquefied gases, methanol, formaldehyde, paraxylene and acetic acid storage tanks (allof them are located at the Sines harbour), the respective pumps, the pipelineconnecting the Sines LNG Terminal to the natural gas transport network and all rotatingequipment.
9. List some advantages and disadvantages of implementing an early warning systemon your industrial installations.
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Advantages: Avoid casualties and damage and evacuate people from buildings. Thetsunami warning can save lives. For fixed equipment, little or nothing can be done;however mobile machinery and vehicles may be taken to a safe area, assuming anotice of at least 20 minutes.
The initial shutdown of pumping devices, piping transport, and similar actions can beactivated within the EEW alert. However, full shutdown will take more time.
Disadvantages: Warning time is not enough to take effective actions. In some cases aFalse Alarm can incur in high costs.
7. Cost-Benefit preliminary analysis
In this section, Fault Tree Analysis (FTA) will be applied to the analysis of an adverseevent associated with the failure of an alarm to generate the appropriate response.
FTA is a structured top-down deductive to failure analysis, starting with a potentialevent called a TOP event, and then determining all the ways it can happen.
Figure 19 presents a preliminary exercise made for Sines, considering the losses (if noEEWS is present) and the gains due to EEWS implementation in a life time of 50 yearswith probability of 39% of exceedance (RP=100 yrs). For the case presented there is aloss reduction (expected value) of about 34.2 M€, which corresponds to a saving of9.7% of total inflicted losses if no EEWS is implemented (E2-E1)/E2.
We have run other cases for checking the influence of other parameters in this savings.
Table 4 presents a sensitivity analysis for changing the Loss Reduction Factor (Lrf) for
two different Return Periods (RP).
Table 4: Sensitivity analysis for changing the Loss Reduction Factor (Lrf ) for two different Return
Periods (RP)
Time life -50 yr Time life -20 yr
Lrf (%) Reduction of Losses (%)IDI=1
Reduction of Losses(%) IDI=1
1 0.7 0.2
2 1.7 1.2
5 4.7 4.210 9.7 9.2
15 14.7 14.2
20 19.6 19.2
Note that Loss Reduction Factor (Lrf) is function of the effectiveness of thepreparedness plans implemented with EEWS and of the degree of IDI (IndustrialDisruption Index – Figure 12). All these results are very preliminary because most ofthe parameters have to be checked with end-users.
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Figure 19. Example of a FTA made for Sines.
E2-E1
E1
E2
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