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Fire Australia 2017 | Quantification of Fire Safety | Fire Safety Engineering Stream
Title Case Study: Risk based approach for the design of a transport infrastructure
Authors
Edmund Ang, Imperial College London | AECOM Australia E: [email protected] | [email protected] Ray Christie, Transport for NSW E: [email protected]
Topics - Risk based fire safety engineering - Methodology and case study
Abstract
In Australia and internationally, the use of the risk based approach for the fire safety design
in buildings and infrastructure are gradually recognised as a viable option in addition to the
currently adopted absolute, i.e. safe or unsafe design approach. The risk based design has
a significant advantage as it recognises the inherent probabilistic nature of a fire risk, and
allows the level of mitigation measures needed plus the acceptance criteria of the risk to be
objectively quantified in line with the probability. In addition, the risk based approach
recognises although there are countless options to potentially eliminate the risks, not all of
these options are effective from a cost benefit perspective.
In this case study, we present the 7 steps risk based approach we adopted for the design of
a 250 m long tunnel to evaluate the necessity to provide a new fire hydrant system in the
tunnel by considering the risk of a fire to the safety of the passengers, to the fire fighters, to
the surrounding areas and to the train operations.
The 7 steps process of the risk based approach includes establishing the baseline
requirement, understanding the acceptance criteria for the risk, to conducting the
probabilistic study of the fire risks and the consequences of the risks. We explained in this
case study the process to integrate the outcome of the risk and consequences assessment
with the potential mitigation measures being considered. This is a key advantage and a key
step in the risk based approach as this method allows us to establish if the mitigation
measure is cost effective, i.e. if the cost outweighs the consequences of the risk.
Whilst the technical approach to a risk based design may change depending on the type of
projects and environment, a suitably implemented 7 step risk based approach can ensure a
more objective outcome to enable decision makers to reach closer to a quantifiably fair and
impartial decision.
1.0 Introduction to Risk Based Design
In Australia and internationally, for the fire safety design of both buildings and infrastructure,
the fire safety design of these developments are often carried out using a combination of
prescriptive guidance, e.g. the Building Code of Australia [1], the National Fire Protection
Association [2] and performance based design.
For the prescriptive guidance, the design based on this approach is relatively straightforward
whereby practitioners need only to follow the prescribed recommendations in these
standards. On the other hand, performance based fire engineering design is used when the
conventional prescriptive guidance cannot be complied with, or a more efficient and safer
design can be achieved by the use of the performance based design.
In the performance based design, for example the IFEG [3] notes a number of approaches
that can be taken for the quantitative analysis including the deterministic approach, i.e. safe
or unsafe or a comparative approach, i.e. benchmarking against code guidance. Whilst the
IFEG recognises a risk based approach exists, and this method has been applied in
establishing the performance requirements of code guidance [4], the risk based design
approach has not been applied extensively by practitioners in the design for fire safety
engineering over the last 20 years compared to the deterministic approach.
Figure 1: Performance Based Solutions with an Absolute and Probabilistic Approaches
In this paper, we discuss the challenges to the widespread adoption of the risk based design,
and examine a case study on the application of this approach in a transport infrastructure.
2.0 Challenges to the Adoption of the Risk Based Design
The risk based design has a significant advantage as it recognises the inherent probabilistic
nature of a fire risk, and allows the level of mitigation measures needed plus the acceptance
criteria of the risk to be objectively quantified in line with the probability. In addition, the risk
based approach recognises although there are countless options to potentially eliminate the
risks, not all options are effective from a cost benefit perspective. The risk based approach
allows this to be quantified objectively.
This is compared to the deterministic approach whereby the viability of a design is based
strictly on a pass fail criteria, ignoring the probability of an event from occurring, e.g. 1 in
1,000 years or 1 in 10,000 years and the cost benefit on the option to reduce the risk, e.g. is
$10,000,000 a justifiable cost in eliminating 5 major injuries per 1,000 statistical years.
Whilst the risk based approach has an advantage over a deterministic approach, we
recognise this approach’s inherent challenges and we see three main challenges with this:
Firstly for a probabilistic analysis, the key input is the quality of the historical data for the
events considered. This is because the outcome of a probabilistic study is determined by
the reliability and accuracy of the data collected. This is compounded by the complexities
including if the historical data is only applicable to one region and the methodology for the
data collection, e.g. the precise definition of a major and minor injury. To overcome this
challenge, an industry body, e.g. Engineers Australia can play a key part in setting a
mutually agreeable standard and methodology for the collection of data.
Secondly, unlike probabilistic analysis with a pass fail criteria, the risk based approach
explicitly recognises an event could occur but with a varying likelihood. This means from an
approvals perspective, there needs to be legally established acceptance criteria that clearly
define what level of risks and consequences are acceptable both from design and legal
perspectives. For this, we believe the government or a state agency is in the strongest
position to establish a minimum benchmark for the acceptance of a risk based design.
Thirdly for the cost benefit analysis which is integral to a probabilistic analysis, a key topic to
be considered is assigning a monetary value to a human life, i.e. the value of a statistical life.
A guideline published by Transport for NSW [5] provided a number of references to the value
of a statistical life.
Table 1: Value of Statistical Life [5]
Value of Statistical Life in NSW (VSL) $6,698,897
Value of Statistical Life Year (VSLY) *Based on a real discount rate of 4% over 40 years
$325,434
Whilst this method is commonly adopted in other disciplines, e.g. National Health Service
(NHS) UK [6] in evaluating whether a type of treatment should be funded, this is still
perceived as a politically challenging topic in the fire safety industry. To overcome this
challenge, we believe a key element is through engaging with the public to help the public
and the stakeholders to understand this is a necessary step in ensuring an equitable
outcome is achieved in the decision making process.
3.0 7 Steps Process to Risk Based Design
From our experience, a possible misconception of the risk based design approach is the
method of analysis is focused solely on the probability of the event, i.e. if the probability of an
event is deemed low enough there would not be a need to put in place a mitigation measure.
Although a probability analysis is a critical element, it only forms part of the process in the
risk based design as illustrated in Figure 2. A key component of the risk based design is that
it combines the probability of an event with the consequences and the cost to implement it.
This way, the cost effectiveness of the mitigation measure can be benchmarked against the
event, and this enables the decision makers to decide if the limited funding should be
channelled to address this risk, or another risk.
A second key component of the risk based design is the design process relies on feedback
from the key stakeholders. This closed loop feedback ensures the design process is refined
in each iteration. In addition as we will demonstrate later, a risk based design often includes
ambiguous or uncertainty. In this instance, active consultations are crucial in achieving a
mutually agreeable decision making process.
Figure 2: Risk Based Design Approach Adopted for the Case Study
4.0 Risk Based Design for Infrastructure
In the current state, the adoption of the risk based design is more frequently seen in the
transport infrastructure due to a number of reasons.
Firstly the risk based approach is enshrined in the Australian Rail Safety National Law and
covered under the approach of So Far As Is Reasonably Practicable, or commonly known as
SFAIRP [7]. The recognition of the risk based approach on a legislative level provided the
legal backing necessary for this approach.
Secondly because of the scale of the projects and due to the finite funding or physical
constraints, often the only viable means of achieving a practical design outcome is through
the use of a risk based approach to quantify the effectiveness of a measure needed against
an event, e.g. a train fire disabled in mid-journey. If only an absolute approach is adopted in
the design analysis, the outcome would show an impractical hundreds of millions of dollars
would be needed to reduce or mitigate this extreme event.
Thirdly as suggested in Figure 2, a key element in the risk based design is the acceptance
criteria of the risk. Although it is possible to show it is not cost effective to mitigate a risk and
its consequences, designers and policymakers accept catastrophic consequences due to an
event will never be tolerable. To determine this, Transport for NSW for example in Figure 3
has a risk ranking framework developed to categorise the tolerability of a given risk based on
the consequences.
Type A risk is not tolerable and an alternative will be needed. Type B to D risks will only be
tolerable if it can be demonstrated, i.e. via a risk based study and cost benefit analysis that
all reasonably practicable mitigations measures have been implemented.
Figure 3: Safety Risk Ranking and Guidelines
In this paper, we present a case study to show how the 7 steps risk based approach is
adopted in the railway industry as we believe the same approach can be adopted in the
wider fire safety engineering design, including in the buildings and industrial sectors.
As the intent is not to focus on the technical details, but to illustrate the 7 steps process for
the risk based approach from conception to conclusion, we have only provided a summary of
the detailed technical design consideration.
5.0 Case Study: Rail Enclosure Structure
5.1 Case Study Introduction
The RES or Rail Enclosure Structure is a short tunnel section located in the rail corridor in
North Sydney. The RES is a 250 m long 24 m wide short tunnel as shown in Figure 4. As
part of the proposed works in the RES, it became necessary to determine if a new fire
hydrant system is required in the RES.
Figure 4: Rail Enclosure Structure (250 m long tunnel section)
Following a desktop review of the current design and standards, we together with the
stakeholders determined a risk based design approach is needed to determine if a new fire
hydrant system is required in the RES.
5.2 Step 1: Identify All Credible Scenarios
The main intention of providing a fire hydrant system in the RES is to allow the fire brigade to
perform fire fighting operations for a fire in the RES. Therefore, the first step of the analysis
is to identify credible scenarios that will result in a fire event in the RES.
We identified the potential scenarios resulting in a fire in RES using the event tree as shown
in Figure 5. For this event tree, we have also undertaken a detailed qualitative analysis
considering each event but this is not included in this paper.
Figure 5: Identification of the Credible Fire Scenarios
5.3 Step 2: Constructing an Event Tree from Event Start to Consequences
Once the credible fire scenario, i.e. the passenger train fire has been established, we have
developed an event tree to example the possible consequences chronologically initiating
from a fire in the RES and the impact due to the absence of the fire hydrant in the RES. The
event tree is based on a passenger train fire caused by equipment failure and arson.
Figure 6: Chronological Event Tree for a Passenger Train Fire
5.4 Step 3: Evaluation of the Probability of the Event
As shown in Figure 6, we have considered the chronological events associated with the
passenger train fires by considering the type of fires (accidental or arson), the severity of the
fire, the location where a train is disabled (within or outside of the RES), and the wind
condition during a detrainment scenario (presence of wind would spread smoke in the RES).
We have established the probability of these events using the relevant statistical data and to
account for the uncertainties, we have also included a margin of safety.
For example, based on the current fire safety provisions which are expected to improve over
time and from the statistic, less than 0.06% of a train fire continues to grow beyond the
inception stage. However in our calculations, we increased this to 1% to account for the
uncertainty and as a margin of safety. By allowing for a margin of safety in each
chronological event from the fire type to the wind condition, this resulted in a compounded
safety margin in the design.
Using the event tree and the probabilities of the events, we derived the likelihood ranking
table in accordance with the Safety Risk Ranking Guidelines in Figure 3.
Table 2: Likelihood Ranking for a Passenger Train Fire Event
Fire Type Wind
Condition Probability
(a)
Probability of major fire
detraining in the RES (b)
Probability of (a) and (b)
Likelihood Ranking
Per Figure 3
Arson
Not adverse 0.8 0.008 0.0064
(1 in 156 years) L6
Adverse 0.2 0.008 0.0016
(1 in 625 years) L6
Equipment failure
Not adverse 0.8 0.0009 0.00072
(1 in 1,389 years) L6
Adverse 0.2 0.0009 0.00018
(1 in 5,500 years) L6
5.5 Step 4: Evaluation of the Consequences of the Worst Credible Events
Based on the event tree analysis conducted in the previous step, we identified the following
worst credible scenarios that would lead to a fire incident within the RES. Once the
likelihood has been established, the next step is to consider the consequence (threat to life
safety) associated with the scenarios. We have considered the following fire scenarios:
1. Scenario 1 – Arson fire with no adverse wind
2. Scenario 2 – Arson fire with adverse wind
3. Scenario 3 – Equipment failure with no adverse wind
4. Scenario 4 – Equipment failure with adverse wind
5. Sensitivity scenario – Arson fire with adverse wind and train stopping near portal.
We have modelled the fire scenarios and the consequences using advanced computer
modelling techniques to establish the tenability conditions in the RES when a passenger
train on fire stops within the RES.
The consequence analysis considered a train carriage on fire stopping in the middle of the
RES. This resulted in the scenario where passengers have to travel the furthest to reach the
portal (open air place of relative safety). However as a sensitivity analysis, an additional
scenario assuming wind blowing southward and the train fire carriage at northward near a
portal resulting in smoke spread along the entire length of the RES is also considered.
The evaluation of the consequences is intended to inform the practitioners and stakeholders
the potential severity of the event.
Figure 7: A Computational Fluid Dynamics Model of a Train Fire in the RES
5.6 Step 5: Determining the Risk Level with the Probability and the
Consequences Combined
From the computer modelling in the previous step and from evaluating the tenability criteria
for a passenger train fire within the RES, we concluded the consequences for the worst
credible scenarios (out of the 5 fire scenarios) are low. See Table 3.
Figure 8: Arson and Equipment Failure Fire Risk Ranking
At this stage, it is important to note although the consequences of the event are considered
low (D), this is not considered satisfactory until it can be demonstrated via a cost benefit
analysis the provision of a fire hydrant system has a net negative value. This is a critical
element, particularly under the Rail Safety National Law and the SFAIRP (So Far As Is
Fire Location
Plan view of the RES Tunnel Portal
Reasonably Practicable) to demonstrate all reasonably practicable mitigation measures have
been implemented regardless of the level of risks or consequences.
5.7 Step 6: Mitigation Measures plus a Cost Benefit Analysis
As part of the cost benefit analysis, it is crucial to establish the consequences cost for
providing and omission of the fire hydrant system in the RES. From consultation with
stakeholders and from a literature review, we established an indicative consequences cost
as shown in Table 3.
Active consultations are important throughout the risk based design process, but specifically
in instances where there is uncertainty, e.g. in the consequences costs in the consideration.
A thorough consultation with stakeholders ensures an informed consensus and a fair
outcome is achieved.
Note that the disproportionate factor is to account for uncertainties in the calculations of the
consequences costs and is a mutually agreed factor with the stakeholders.
Table 3: Likelihood Ranking for a Passenger Train Fire Event
Impacted Areas No Fire Hydrants With Fire Hydrants
Delay in Restoring Service in the RES 6 days 3 days
Loss in Ticket Sales $94k per day $94k per day
Material and Engineering Costs $100k per day $100k per day
Other costs (legal, management and reputational) Factor of 3 Factor of 2
Total Indicative Consequences Costs $3.49m $1.16m
Indicative Disproportionate Factor (2 to 5) $6.98m to $17.45m $2.32m to $5.8m
Using the consequences costs, and considering the costs for providing a fire hydrant system,
we derived the cost benefit analysis for the provision of the fire hydrant with the probability of
the fire event factored in. This is summarised in Table 4.
Table 4: Cost and Benefit Analysis
Variables Description
Total cost for providing the fire hydrant $1.32m
Probability of an arson fire escalating into a
major fire within the RES (no adverse wind)
1 in 156 years or 0.0064
Consequences cost for omitting the fire
hydrant system
$6.98m to $17.45m
Consequences cost for providing the fire
hydrant system
$2.32m to $5.8m
Design life of the fire hydrant system 30 years
With Fire Hydrant No Fire Hydrant
Consequence cost with the probability of the
event factored in
($2.32m to $5.8m) x 0.0064 =
$0.014m to $0.037m per year
($6.98 to $17.45m) x 0.0064 =
$0.044m to $0.11m per year
Consequences cost over 30 years
(design life of a typical fire hydrant)
$0.014m to $0.037m per year
over 30 years =
$0.42m to $1.11m
$0.044m to $0.11m per year
over 30 years =
$1.32m to $3.3m
As per the analysis above, the consequences cost for omitting the fire hydrant over 30 years
is indicatively between $1.32m to $3.3m. The cost of providing and maintaining the fire
hydrant is at $1.32m. Separately as shown in the consequences cost where a fire hydrant is
installed, the consequences cost + the installation of the fire hydrants mean the combined
costs are between $1.74m to $2.43m.
Comparing $1.74m to $2.43m (with fire hydrant) to the consequences cost without a fire
hydrant system $1.32m to $3.3m, the difference is between –$0.42m to $0.87m where the
negative means the cost to install the fire hydrant is not beneficial.
This outcome is normal in a risk based design whereby depending on the sensitivity of the
consideration, i.e. the disproportionate factor and the cost to install the fire hydrant, the cost
benefit analysis could show the provision of a fire hydrant provides a net positive outcome.
This scenario demonstrates the importance of consultation as in our experience, a risk
based approach will involve a number of uncertainties and the best outcome can often be
achieved by active consultations with the key stakeholders.
5.8 Step 7: Consultation with the Stakeholders
As we discussed earlier, an important step in the risk based design is to consult with the key
stakeholders and to ensure their feedbacks have been accounted for in the design.
From our discussions with the various stakeholders including various state agencies, a
consensus was reached that although the cost benefit analysis shows the provision of a new
fire hydrant system in the RES can be a net negative, the cost involved is negligible when
considering the proposed works in this rail corridor.
Based on the above, the stakeholders agreed a fire hydrant system should be provided.
5.9 Discussions
From the case study, we demonstrated the decision making process for the provision of a
new fire hydrant system can, and have been quantitatively assessed and considered.
In this instance, although the outcome where a fire hydrant system should be provided may
have been foreseeable, this is often not the case when considering other complex
engineering designs. For example the design of an open gangway in a train carriage
compared to compartmented train carriages. This requires consideration not only from a fire
incident perspective, but also from a daily passenger security perspective.
Without an approach that can quantify these considerations, it is unlikely a fair and equitable
outcome can be reached, and in the unfortunate scenario where an accident occurs,
indefensible questions will be raised as to why one decision has been made in favour of
another. With a quantitative risk based design approach, practitioners will be able to
demonstrate the thought and design process that has been considered to reach an outcome.
6.0 Conclusions
In this paper, we discussed the benefit and challenges to the adoption of the risk based
design approach in solving engineering challenges. In addition, we provided a 7 steps
design process for the risk based design approach that combines both a probability plus a
cost benefit analysis.
Whilst the technical approach to a risk based design may change depending on the type of
projects and environment, fundamentally the process to consider for the risk based design
will be in line with the 7 steps we have outlined, from considering the credible scenarios to
carrying out a cost benefit analysis plus active consultation with stakeholders.
The intent of the case study in this paper is to demonstrate the application of the 7 steps
process. Often in a risk based design, there is a misconception this design approach is only
on considering the probability of an event, disregarding to the consequences and the cost
benefit of the measures to mitigate the event. With a suitably implemented risk based
design approach, it is possible to enable decision makers in reaching an equitable outcome
which may not always be attainable when using an absolute analysis approach.
In engineering and other disciplines with finite resources, a suitably implemented risk based
approach can ensure a more objective outcome. This is in our opinion a beneficial approach
in assisting decision makers to reach closer to a quantifiably fair and impartial decision.
7.0 References
[1] Australian Building Codes Board. The National Construction Code – Building Code
of Australia. ABCB, April 2016
[2] National Fire Protection Association. NFPA 101: Life Safety Code. NFPA, January
2015.
[3] Australian Building Codes Board. International Fire Engineering Guidelines. ABCB,
March 2015.
[4] B. Meacham. Performance-Based Building Regulatory Systems – Principles and
Experiences. IRCC, February 2010.
[5] Transport for NSW. Principles and Guidelines for Economic Appraisal of Transport
Investment and Initiatives. TfNSW, March 2013.
[6] National Institute for Health and Care Excellence. Developing NICE guidelines: the
manual. NICE, October 2014.
[7] New South Wales Government. Rail Safety National Law (NSW) No 82a. [Online]
[http://www.legislation.nsw.gov.au/#/view/act/2012/82a], December 2016 [Accessed
on March 2017].