EXECUTIVE SUMMARY
Background
Seismic risk assessment continues to evolve in the Puget Sound region, as well as in other
parts of the world. Utilities like Seattle Public Utilities (SPU) are working to better understand
these risks, and making the investments needed to address them, while continuing to deliver
drinking water and other essential water provision services to their customers.
In 1990, the Seattle Water Department, which merged with other city departments in 1997 to
form SPU, commissioned a seismic study of its water system. The work was initiated in
response to growing concern about seismic risk. Cygna Energy Services (Cygna) conducted
this comprehensive seismic vulnerability assessment.
For the past 28 years, SPU has been addressing the issues identified in the Cygna assessment,
as well as planning for and incorporating modern seismic standards into new projects as
mandated by federal and state regulations. Many vulnerable facilities have already been
upgraded to the seismic standards developed by Cygna, and over $60 million has been spent
on making seismic upgrades to existing infrastructure. New facilities, such as SPU’s buried
terminal reservoirs, were designed and constructed to remain functional if subjected to the
ground-shaking levels stipulated by the Seattle Building Code.
Since 1990, scientific knowledge about the impact of earthquakes on water systems has
increased dramatically, and understanding of the seismicity of the Puget Sound region—in
particular the Seattle Fault Zone and the Cascadia Subduction Zone—has also advanced
substantially. Growing understanding of these risks led SPU to conduct another seismic study in
2016 and 2017. This report summarizes the findings of SPU’s current seismic vulnerability
assessment of its water system, and updates and expands the seismic vulnerability assessment
completed by Cygna.
The overall goal of this new study was to incorporate the current understanding of seismic risk
into long-term planning for SPU’s water system. The SPU water system was evaluated for a
M7.0 (magnitude 7.0) Seattle Fault Zone (M7.0 SFZ) earthquake and a M9.0 Cascadia
Subduction Zone (M9.0 CSZ) earthquake scenario. Each facility was also evaluated for ground
shaking levels approximately equal to the current Seattle Building Code ground shaking levels.
Performance- and goal-based approaches were used to establish a cost-effective set of shortterm and long-term strategies that will help to ensure service to SPU’s customers after a seismic
event.
This study incorporates the strategy that planning for seismic risk needs to be an ongoing part
of a utility’s business model and includes a prudent funding strategy and progressive
investments over time. It recommends targeting shorter-term investments for the higher-risk
areas of the system, while planning for longer-term investments in upgrades.
This study fits into SPU’s broader resiliency framework, which aims to ensure that infrastructure
will remain functional in a natural disaster and service levels will be restored as soon as
possible, as well as cope with climate changes and other events.

ES-1

 EXECUTIVE SUMMARY

Key Findings
Seismicity and Seismic Hazards
The chance of a major, catastrophic earthquake similar to the 2011 Tohoku (east Japan)
earthquake, or 2011 Christchurch (New Zealand) earthquake striking Seattle in the next 50
years is approximately 15% to 20% (based on a 5% chance of a M6.5 or larger Seattle Fault
Zone earthquake and a 14% chance of a M9.0 Cascadia Subduction Zone earthquake (Steele
2013)). Less catastrophic, but more frequently occurring earthquakes, such as the 2001
Nisqually earthquake, are also concerns. There is an approximately 84% chance there will be
another earthquake similar to the M6.8 Nisqually earthquake in Seattle in the next 50 years
(Steele 2013).
In addition to intense ground-shaking, many of SPU’s transmission and direct service areas are
subject to liquefaction, landslides, settlement, and fault-rupture hazards that could result in
permanent ground displacement ranging from a few inches to over 10 feet during a major,
catastrophic earthquake. Even in a Nisqually-type earthquake, ground-shaking could be intense
in the epicentral region and could result in significant permanent ground displacements,
although the areas of intense ground shaking and permanent ground displacements would not
be as widespread as in a catastrophic earthquake.
SPU’s Water System Seismic Vulnerability
Similar to many other water utilities in the United States, SPU’s water system would likely suffer
significant damage and disruption during a catastrophic earthquake like the 1995 and 2011
earthquakes in Japan, or the 2011 New Zealand earthquake. Computer modeling suggests that
water pressure could be lost throughout SPU’s water system within 16 to 24 hours for the M7.0
SFZ or M9.0 CSZ earthquake scenarios considered in this study. It could take about a month
until water service would be restored to 70% of SPU’s direct service customers, and two months
or more until water service would be restored to all direct service customers. Much like Los
Angeles Department of Water and Power after the 1994 Northridge earthquake, to restore preearthquake reliability and service levels to SPU’s water system would likely take years after a
major earthquake.
Although system response to a Nisqually-type earthquake was not evaluated during this study,
there was no significant disruption to SPU’s water system during the 2001 earthquake or similar
earthquakes in 1949 and 1965. It is possible that a slightly larger Nisqually-like earthquake
located closer to Seattle could cause more significant damage to SPU’s water system, but it
would be considerably less than the impacts from the earthquake scenarios used in this study.
Increasing the Seismic Resiliency of SPU’s Water System
There are proven technologies and strategies that water utilities in the United States, Japan and
New Zealand are implementing to mitigate and/or prevent water system damage. They include
installing earthquake-resistant pipe, upgrading existing facilities to meet current seismic
requirements, ensuring there is adequate water storage to provide emergency water after a
ES-2

 EXECUTIVE SUMMARY
major earthquake and stockpiling repair materials. Implementing these technologies is
expensive and could take decades.
There are less costly short-term measures, such as improving emergency preparedness and
response planning, and adopting isolation and control strategies, that can be used to mitigate
the effects of seismic damage until expensive long-term infrastructure improvements can be
made. The cost of these short-term measures is on the order of $40 to $50 million over the next
15 to 20 years. Long-term infrastructure improvements will cost over $800 million over
approximately the next 50 years, followed by further investment for decades.
Over the next 20 years, the recommended strategy is to
1. Improve earthquake-emergency preparedness and response planning, and develop
post-earthquake isolation and control strategies;
2. Begin upgrading critical transmission pipelines in discrete areas with the highest
hazards;
3. Continue upgrading key vertical facilities (such as buildings and water storage facilities);
4. Construct new facilities in accordance with modern, performance-based seismic codes;
5. Use pipeline systems that can resist the expected seismic hazards along the alignment.
When new pipelines are installed or existing pipelines replaced, use pipeline systems
that can resist the expected seismic hazards along the pipeline alignment.
After the first 20 years, continue to focus on remaining critical facility upgrades and upgrading
transmission pipelines in the remaining hazard areas, including the zones susceptible to
liquefaction, landslide, and fault offset.

Identification and Definition of Seismic Hazards
The tectonic setting for the Pacific Northwest is shown on Figure ES-1. It is characterized by
subduction of the Juan de Fuca tectonic plate beneath the North American Plate, as well as
north-south compression caused by the Oregon block of the North American Plate pushing the
Washington block into the stationary Canadian block.
Three potential earthquake scenarios threaten the Puget Sound region:
1. Interplate subduction earthquake:
This occurs when stresses/forces created as the Juan de Fuca Plate attempts to
slide underneath the North American Plate exceed the forces locking the two
plates together at their boundary. This fault is capable of rupturing off the coast
from Northern California to southern British Columbia and could produce
magnitude 9.0 (M9.0) or greater earthquakes. Although the ground motions from
a large subduction earthquake would be attenuated somewhat by the time they
reached Seattle, strong ground-shaking could last for three or four minutes.
2. Deep intraplate earthquake
This would occur in the upper portion of the Juan de Fuca Plate directly below
Puget Sound. Although these earthquakes may reach M7.0 to 7.5, due to their
ES-3

 EXECUTIVE SUMMARY
typical depths of 40 to 60 kilometers, the ground-motions would be somewhat
attenuated by the time they reached the surface and would not be as large as
ground motions from a similarly sized shallow earthquake.

Figure ES-1. Potential earthquake sources in the Pacific Northwest (United States Geological Survey
2001)

3. Shallow crustal earthquake
These earthquakes are caused by compression of the Washington block of the
North American Plate and may reach M7.0 to 7.5. Because these shallow
earthquakes may occur within a few miles of the earth’s surface, ground-shaking
intensity in Seattle will be more than twice as strong as the intensity for the
interplate event, and more than five or six times as strong as the ground-shaking
intensity that occurred in Seattle during the 2001 Nisqually earthquake.
ES-4

 EXECUTIVE SUMMARY
In addition to ground-shaking, earthquakes can cause unstable soils to liquefy (in other words,
lose shear and bearing strength and behave like a liquid), slide, and settle. Earthquakes also
trigger landslides. A crustal earthquake could produce surface fault offsets of three to five
meters in the Seattle area. Permanent ground displacements are the primary cause of the
buried pipeline damage that has plagued water utilities (and other systems with buried
pipelines) in past earthquakes.
Figure ES-2 shows the areas where permanent ground displacements are most likely to occur.
There are also likely to be isolated, unidentified areas where permanent ground displacements
could also occur, but they would probably not be as widespread.
Earthquake ground motions, such as peak ground acceleration, were estimated using current
ground motion attenuation models for the M7.0 SFZ and M9.0 CSZ scenarios. The 2014 United
States Geological Survey (USGS) 0.02 probability (2% chance) of exceedance in 50 years
(2,475-year average-return interval) peak ground accelerations (2014 USGS Ground Motions)
were also incorporated in this work. Regional seismic hazard mapping and models were used to
estimate permanent ground displacements for the two earthquake scenarios. Section 2
summarizes the hazard analyses.

Vertical Facility (Nonpipeline) Assessments
SPU’s water system facilities were evaluated for the two earthquake scenarios and the 2014
USGS Ground Motions. Facility assessments included office and maintenance buildings, pump
stations, gatehouses, reservoirs, elevated tanks, and standpipes. The estimated likelihood of
each facility remaining functional for each scenario was cross-referenced against the facility’s
criticality. Pseudostatic methodologies (as opposed to complex dynamic analyses) were used to
estimate vertical facility response.
SPU’s newer (and generally largest) treated water storage reservoirs are expected to perform
well in significant earthquakes. Recommended action includes further seismic analyses and
upgrades to some of the older storage reservoirs, older buildings, and some smaller elevated
tanks and standpipes. Section 3 contains a detailed description of the facility assessments,
along with a summary table of the results.

Pipeline Assessments
SPU classifies its pipelines into two categories: transmission and distribution. In general,
transmission pipelines are the larger diameter pipelines that carry water from the mountain
reservoirs into SPU’s direct service area and to wholesale customers. Distribution pipelines are
the smaller diameter pipelines that convey water to customers within the direct service area.
Different seismic analysis methods were used for the two pipeline classes. Transmission
pipelines were evaluated using a high-level approach. Regional seismic hazard maps were
used to identify locations where the transmission pipelines pass through permanent ground
ES-5

 EXECUTIVE SUMMARY

displacement areas. Those areas judged to have the most significant hazards were visited by
members of the project team. Based on the pipe construction materials and engineering
judgment regarding the permanent ground displacement potential, expert opinion was used to
predict the likelihood that the pipe would remain functional for each earthquake scenario.
Significant findings include the need for seismic upgrades and/or emergency response plans at
several discrete locations, including







Cedar River Pipelines 1, 2, 3 at Renton;
Cedar River Pipelines 1, 2, 3 at the Martin Luther King Way slide area;
Cedar Eastside Supply Line at the Cedar River Crossing;
Tolt Pipelines at Norway Hill;
West Seattle Pipeline at the Duwamish River Crossing;
Cedar River Pipeline 4 at the Green River Crossing.

Additionally, there are other areas that warrant further investigation along these transmission
pipeline routes, particularly in areas of potential liquefaction, landslide, settlement, and fault
rupture. These will be the focus of follow-up studies.
Distribution pipelines were assessed using the American Lifelines Alliance (ALA) watermain
vulnerability equations. The equations use peak ground velocity, permanent ground
displacement, and pipeline characteristics to estimate the number of pipe failures.
Approximately 2,000 distribution pipeline failures (repairs) were estimated for the M7.0 SFZ
scenario, and approximately 1,400 were estimated for the M9.0 CSZ scenario. Areas
susceptible to permanent ground displacement (liquefaction, landslide, settlement, and fault
rupture) are the highest concern. The pipeline damage would result in water losses that could
drain the water system after an earthquake.
These pipeline failure estimates are generally consistent with the performance of water utility
pipeline systems in previous earthquakes. It is important to note that due to the many
assumptions and approximations that went into these estimates, the actual number of pipe
repairs in these scenarios could vary by as much as plus or minus 50%. Section 4 contains a
detailed description of the pipeline assessments and a summary table of the results.

System Analysis
The facility and pipeline assessments were combined with computer hydraulic model analysis to
estimate the water system response to, and recovery from, catastrophic earthquakes, such as
the M7.0 SFZ and M9.0 CSZ scenarios. The USGS Ground Motions would not occur
simultaneously throughout the SPU system, since they are derived from different earthquake
sources, so a system analysis was not performed for these ground motions.
The results suggest that in either the M7.0 SFZ or M9.0 CSZ scenarios, the best estimate is that
SPU’s direct service area would completely lose pressure within 16 to 24 hours. Typically, as
ES-6

 EXECUTIVE SUMMARY

Figure ES-2. SPU water system earthquake hazards map (note: Seattle Fault Zone is believed to extend east of the shaded area that is shown out to the Cascade Mountain foothills)

ES-7

 EXECUTIVE SUMMARY

 

[this page left intentional/y blank]

ES-8

EXECUTIVE SUMMARY
reservoirs and tanks drain due to water pipe leaks and breaks, the pressure would be lost in
higher elevation pressure zones first.
Loss of water pressure within 16 to 24 hours is consistent with what has happened to other
water utilities in catastrophic earthquakes. However, uncertainty remains regarding actual
ground motions, permanent ground displacements, facility and pipeline responses, operating
conditions at the time of the earthquake, and operational response. It is possible that the system
could drain more rapidly or slowly than the best estimate suggests.
It is likely that both earthquake scenarios would have a significant impact on the major
transmission pipelines. Although distribution pipeline repairs would start almost immediately
after an earthquake, it could take up to six to eight weeks to make even temporary repairs to
transmission pipelines in areas such as underground river crossings or steep slopes. Estimates
of water service restoration times are shown on Figure ES-3.

Figure ES-3. Retail service area restoration estimates after catastrophic earthquakes: current condition,
after 20+ years of seismic upgrades, and after 50+ years of seismic upgrades

The 1949, 1965, and 2001 Puget Sound area intraplate earthquakes show that the effects from
future intraplate earthquakes on SPU’s water system would be much less than the impacts from
the two scenario earthquakes modeled by this study. It is possible that a future intraplate
earthquake could be slightly larger (e.g., M7.5) than recent intraplate earthquakes, and occur
ES-9

 EXECUTIVE SUMMARY
directly below SPU’s direct service area, and result in more significant impacts. These impacts
would still be significantly less than the impacts estimated for this study’s earthquake scenarios.

Treated Water Storage
The current study also analyzed the effect and importance of treated water storage for response
and recovery after catastrophic earthquakes. A previous system reliability analysis, which was
based on less severe water outage assumptions, had recommended downsizing some treated
water reservoirs, and decommissioning two of them (Roosevelt Reservoir and Volunteer
Reservoir) to provide more cost-effective water service for ratepayers. In this study, the role of
storage in post-earthquake recovery was reassessed, since the study also identified the
potential for more significant water outages than had previously been identified.
The role of treated water storage was analyzed in three ways:
1. Comparing storage relative to water demands against the storage available at other
West Coast water utilities, especially those having completed (or currently undergoing)
seismic planning analyses
2. Using computer hydraulic model analyses to estimate the impact of storage on
postseismic response and recovery
3. Examining other factors, such as operational flexibility and resiliency
Based on the analysis, additional storage is needed. Roosevelt and Volunteer Reservoirs
should remain part of SPU’s drinking water system. Since they are not covered reservoirs,
recent regulations have determined that the water is nonpotable, which has resulted in both
reservoirs being disconnected from the drinking water system. However, for emergency
response purposes, the two reservoirs could be configured to provide emergency water. In the
future, they may be upgraded to potable water reservoir standards.
Section 5 discusses water system post-earthquake performance and restoration.

Performance Goals, Mitigation Recommendations, and Cost Estimates
The replacement value for SPU’s distribution system watermains is approximately $19 billion
(SPU 2018b). It is not economically feasible to replace all of the seismically vulnerable assets
over a short period of time. Water system performance goals are needed so customers know
what seismic mitigation funds would provide in terms of overall system performance and help
prioritize facilities for mitigation. Performance goals will also help stakeholders know what to
expect after a major earthquake.
Performance Goals
SPU drafted performance goals that were modeled after the Oregon Resilience Plan (Oregon
Seismic Safety Policy Advisory Commission 2013), using the following metrics:
ES-10

 EXECUTIVE SUMMARY







Providing fire suppression water immediately after an earthquake
Providing water to essential facilities, such as hospitals and other emergency response
centers
Providing water to SPU’s direct service area and customers
Providing water to SPU’s wholesale customer turnouts
Providing emergency drinking water supply

And there are two sets of performance goals:



2045 Goals, which are based on a 20-year plan for seismic upgrades
2075 Goals, which are based on an additional 30 years of seismic upgrades

Inherent in the performance goals and system improvements is that life-safety risks, such as
occupied-building collapse, are not acceptable.
A detailed description of performance goals and system improvements is presented in Section
6.
Mitigation Strategies
To increase the seismic resiliency of SPU’s water system and meet the performance goals, five
general strategies were developed. These strategies are intended to complement one another.
They were designed to cost-effectively mitigate facility damage that is currently expected under
the earthquake scenarios until long-term infrastructure seismic improvements can be made.
The five strategies are:
1. Isolation and control
a. Add isolation systems to appropriate reservoirs so that reservoirs do not
completely drain out if there is excessive pipeline damage. Note that newer
reservoirs, representing more than half of SPU’s direct service area system
storage, already have seismic isolation valves installed.
b. Evaluate the feasibility of isolating those areas within the distribution system
where large amounts of pipeline damage and water leaks would drain reservoirs.
2. Transmission pipelines
a. In the next 20 years, reduce the expected transmission pipeline restoration times
by:
i. Seismically upgrading those critical locations, such as slide areas and
river crossings, which could take weeks to months to repair after a
catastrophic earthquake;
ii. Evaluating the need for, and installing as applicable, line valves and
manifolds in selective locations to decrease restoration times;
iii. Developing a response plan and the repair resources so that those
transmission pipeline failures that occur can be repaired within 7 to 10
days.
ES-11

 EXECUTIVE SUMMARY
b. After 20 years, continue to improve the seismic reliability of critical transmission
lines through seismic upgrades in the remaining high seismic risk areas. This
includes sections of the Cedar River Pipelines, Tolt Pipelines, Cedar and Tolt
Eastside Supply Pipelines, and West Seattle Pipeline. Areas of focus include
fault zones, liquefaction zones, and landslide-prone areas.
3. Seismic-resistant design for new water system assets
a. Require the use of earthquake-resistant pipe per new seismic design standards
described in Section 8:
i. When new pipelines are installed or replaced in areas that are susceptible
to permanent ground displacements;
ii. For watermains that are essential for firefighting (mains needed to provide
water within 2,500 feet of anywhere within the direct service area);
iii. For watermains that serve essential facilities, such as hospitals and
emergency response centers.
b. Require site-specific seismic design when transmission pipelines are replaced or
rehabilitated.
c. Require that new vertical facilities be designed to remain functional for the
American Society of Civil Engineers (ASCE) 7 seismic design ground motions
(which are typically adopted by the Seattle Building Code).
4. Seismic upgrade projects for vertical facilities
a. Seismically retrofit the most critical water system facilities, including office and
maintenance buildings, pump stations, gatehouses, reservoirs, elevated tanks,
and standpipes.
5. Emergency preparedness and response planning
a. Identify additional repair materials and resources needed, either to stockpile in
strategic locations, or to obtain after a seismic event.
b. Place particular emphasis on resources and materials needed for large diameter
pipeline repair with the goal of reducing outage times.
c. Augment existing strategies and resources needed to provide emergency
drinking water after an earthquake.
d. Develop a hazard-specific response plan for earthquakes that fits within the SPU
emergency management approach
The mitigation approach is presented in more detail in Section 6. Recommended improvements
to emergency preparedness and response planning are described in Section 7.
Seismic Design Standards for New Water System Assets
One of the most cost-effective mitigation strategies that SPU can implement is to make sure that
all new facilities meet modern/current seismic code requirements. Most vertical facilities, such
as buildings and tanks, are covered by these requirements. Those facilities needed to operate
the water system or respond in the event of an earthquake should be designed as essential
facilities.

ES-12

 EXECUTIVE SUMMARY
Currently, there are not any water utility industry seismic design requirements for buried
pipelines. There are, however, several types of pipelines that have proven to be earthquakeresistant. Some of these systems, such as earthquake-resistant ductile-iron pipe, are becoming
available in the United States. In Japan, there have been almost no failures in earthquakeresistant pipe. Because SPU and other West Coast water utilities are on the forefront of using
earthquake-resistant ductile-iron pipe in the United States, there have been some initial
challenges. But by switching to these systems when older pipelines are retired, water utilities
can greatly reduce the potential for earthquake damage to their systems.
As part of this seismic assessment, SPU has developed new seismic design standards for its
buried pipelines. SPU plans to incorporate these newly developed seismic design standards for
buried pipe into its Design Standards and Guidelines, following a formal review and acceptance
process. The new proposed standards are discussed in Section 8 and included in Appendix D.
Expected Response After Seismic Improvements
Based on these mitigation recommendations, estimated water restoration time to the direct
service area is shown on Figure ES-3 for current conditions, after 20 or more years of seismic
upgrades, and after 50 years of seismic upgrades. The figure shows a range of response times
for each case. Best and worst case assumptions, discussed in Section 5, were used to as an
indicator of the uncertainty inherent in the analysis. The worst case “as-is” restoration curve
assumes that only water from the Seattle Wells is initially available and that it takes three weeks
to begin to restore the Cedar and/or Tolt system. The best case “as-is,” year 2045 and year
2075 cases assume enough water is being conveyed to the direct service area (distribution
system) to supply those parts of the distribution area that remain or have been restored to
service. It should be noted that response and recovery efforts would be focused on critical
customers, most notably emergency care centers at major hospitals.
Cost Estimates
The recommended long-term mitigation plan is shown in Table ES-1. The recommendations
span five decades and beyond. With each project that is initiated, an engineering options
analysis would be prepared with detailed recommendations. Detailed scopes, cost estimates,
and schedules reflecting a greater level of site-specific analysis will be needed for each project.
Estimated costs are likely to change over time.

ES-13

 EXECUTIVE SUMMARY

 

[this page left intentional/y blank]

ES-14

EXECUTIVE SUMMARY
Approximate Time Frame (values in 2018 dollars)
Mitigation Element
2018 – 2022
2023 ‐ 2027
2028 ‐ 2032
2033 ‐ 2037
2038 ‐ 2042
2043 ‐ 2047
2048 ‐ 2052
2053 ‐ 2057
2058 ‐ 2062
2063 ‐ 2067
2068 ‐ 2072
Isolation and Control
   Analysis
$50,000
   Reservoir and Tank Seismic Valves
$5,000,000
$5,000,000
   Distribution System Isolation Valves
$5,000,000
$5,000,000
   Transmission System Isolation Valves
$5,000,000
$5,000,000
Transmission Pipelines ‐ Discrete Locations
   Analysis/Design
$500,000
   CRPLs in Renton
$35,000,000
$40,000,000
   CRPLs in MLK Slide Area 
$20,000,000
$20,000,000
$10,000,000
$10,000,000
   CESSL in Cedar R. Liquefact & Slide Area
   TPLs in Norway Hill
$15,000,000
$15,000,000
   WSPL Duwamish River Crossing
$10,000,000
$10,000,000
   Other point location upgrades, including TPLs in 
$1,000,000
$2,000,000
$2,000,000
$2,000,000
$2,000,000
$2,000,000
$2,000,000
$2,000,000
$2,000,000
$2,000,000
Bent/Pile Support Crossings
  CRPL No. 4 in Green River Crossing
$6,500,000
$6,500,000
These numbers assume total replacement of remaining pipe segments in liquefiable, landslide, or fault zones. This approach reflects a most conservative approach, and there may be more cost‐effective strategies, including 
Transmission Pipelines ‐ Other Areas Along 
waiting until the pipe sections are replaced due to end of life, and blending emergency response and targeted upgrades.
Pipeline Routes
   Seismic Resistant CRPL (1 CRPL)
$20,000,000
$20,000,000
$20,000,000
$20,000,000
$20,000,000
$20,000,000
   Seismic Resistant TPL (focus on area of only 
$12,000,000
$12,000,000
$12,000,000
$12,000,000
$12,000,000
$12,000,000
one TPL, assumes total slipline)
   Seismic Resistant TESSL/CESSL
$15,000,000
$15,000,000
$15,000,000
$15,000,000
$15,000,000
$15,000,000
   WSPL Duwamish River Valley
$10,000,000
$10,000,000
$10,000,000
$10,000,000
EQ‐Resistant Critical Pipelines
(Distribution Watermain Focused)

$10,000,000
$10,000,000
$10,000,000

$75,000,000
$40,000,000
$20,000,000
$30,000,000
$20,000,000
$19,000,000
$13,000,000

$120,000,000 Total cost $244M ‐ half in years 20‐50, half after that
Total cost $144M ‐ half in years 20‐50, half after that
$72,000,000
$90,000,000 Total cost $186M ‐ half in years 20‐50, half after that
$40,000,000 Total cost $80M ‐ half in years 20‐50, half after that

$20,000,000

$20,000,000

$150,000,000
$400,000 trans. pipelines, trenton tanks, control works bldg., occ wh and tolt chl. bldg
$100,000
$10,000,000
$12,000,000
$12,000,000
$5,000,000
$10,000,000 Placeholder ‐ options analysis beginning 2018. Eval. indep. of seismic study
$12,000,000
$2,000,000 Assumes roof‐to‐wall connection upgrade only
$7,500,000
$5,000,000
$5,000,000
$4,000,000 Only if determined to be life safety concern and standpipe is needed
$4,000,000

$1,500,000
$100,000
$1,000,000
$1,000,000
$300,000
$4,000,000
$1,600,000
$100,000
$2,000,000
$2,500,000
$4,000,000
$1,000,000
$500,000
$1,000,000
$500,000
$1,000,000
$2,000,000
$1,000,000
$1,000,000
$6,000,000
$2,000,000
$2,000,000

$50,000

$15,000,000

$15,000,000

$0

$0

$0

$0

$0

$0

$0

$0

$30,050,000

$500,000

$36,000,000

$42,000,000

$47,000,000

$47,000,000

$12,000,000

$12,000,000

$2,000,000

$2,000,000

$8,500,000

$8,500,000

$217,500,000

Distribution Pipes
Facilities
Emergency Preparedness

$0
$2,500,000
$400,000
$6,000,000

$0
$5,000,000
$31,100,000
$2,000,000

$0
$7,500,000
$17,900,000
$2,000,000

$0
$10,000,000
$23,900,000
$0

$0
$12,500,000
$19,800,000
$0

$47,000,000
$15,000,000
$11,000,000
$0

$47,000,000
$17,500,000
$11,000,000
$0

$57,000,000
$20,000,000
$4,000,000
$0

$57,000,000
$20,000,000
$0
$0

$57,000,000
$20,000,000
$0
$0

$57,000,000
$20,000,000
$0
$0

$322,000,000
$150,000,000
$119,100,000
$10,000,000

Total (5‐yr increments)
Total per 5‐year increment
Total per year

$9,450,000
$1,890,000

$89,100,000
$17,820,000

$84,400,000
$16,880,000

$80,900,000
$16,180,000

$79,300,000
$15,860,000

$85,000,000
$17,000,000

$87,500,000
$17,500,000

$83,000,000
$16,600,000

$79,000,000
$15,800,000

$85,500,000
$17,100,000

$85,500,000
$17,100,000

Transmission ‐ Other Areas Along Pipeline Routes

Notes

These numbers are on top of separate annual costs for replacing/rehabilitating distribution pipes. They reflect the additional costs to make upgrades seismically resistant where needed.

   EQ Resistant Pipe in PGD Areas
$2,500,000
$5,000,000
$7,500,000
$10,000,000
$12,500,000
$15,000,000
$17,500,000
$20,000,000
$20,000,000
Vertical Facilities
These numbers reflect relatively conservative assumptions for full functionality after the design earthquake. Other approaches, such as performance‐based criteria, will be considered.
   Analysis/Design
$400,000
Storage
$100,000
   Myrtle Elevated Tank No. 2 Pipe Clearance
   Riverton Heights Reservoir
$10,000,000
   Eastside Reservoir
$12,000,000
   Beverly Park Elevated
$12,000,000
   Control Works Surge Tanks
$5,000,000
   Cascades Dam
$5,000,000
$5,000,000
   Volunteer Standpipe
$12,000,000
   Magnolia Reservoir
$2,000,000
   Magnolia Elevated Tank
$7,500,000
   Richmond Highlands #2
$5,000,000
$5,000,000
   View Ridge Reservoir
   Foy Standpipe
$4,000,000
   Charleston Standpipe
$4,000,000
Staffed Buildings
   North Operations Center
$4,000,000
   OCC Warehouse
$1,500,000
   OCC Admin Building
$100,000
   OCC Meter Shop
$1,000,000
$1,000,000
   OCC Pipe Carpentry Shop
   Lake Youngs Office Building
$300,000
   OCC Vehicle Maintenance Building
$4,000,000
Other Buildings
   Nonstructural Upgrades
$400,000
$400,000
$400,000
$400,000
   Tolt Reservoir Bridge Connection
$100,000
   Maple Leaf Gate House
$2,000,000
   Roosevelt Gate House
$2,500,000
   Lincoln Gatehouse/Pump Station
$4,000,000
   Broadway Pump Station
$1,000,000
$500,000
   Boulevard Pk and Riverton Well Emerg. Power
   Landsburg Tunnel Gatehouse
$1,000,000
   Lake Youngs Pump Station (old)
$500,000
   West Seattle Pump Station
$1,000,000
   Trenton Pump Station
$2,000,000
   Fairwood Pump Station
$1,000,000
   Lake Forest Park Chlorination
$1,000,000
Emergency Preparedness & Response Planning
   Repair Mat'l & Resource Acquisition
$6,000,000
   Post‐EQ Response Plan Augmentation
$1,000,000
$1,000,000
$1,000,000
$1,000,000
   Post‐EQ Emerg Drinking Wtr Supply Stations
Subtotals
Isolation and Control
Transmission ‐ Discrete Locations

Total

Table ES-1. Recommended mitigation plan summary and order of magnitude cost estimates

ES-15

$848,650,000

Ongoing study about staff buildings
Ongoing study about staff buildings
Ongoing study about staff buildings
Ongoing study about staff buildings
Ongoing study about staff buildings
Ongoing study about staff buildings

 EXECUTIVE SUMMARY

 

[this page left intentional/y blank]

ES-16