Energy Resilience
Solutions for the
Puerto Rico Grid

Final Report
June 2018

United States Department of Energy
Washington, DC 20585

 List of Acronyms
Act 57
ADMS
AIS
AMI
ANL
ARRA
BFE
CAIDI
CHP
CILT
CIP
CRS
DER
DERMS
DHS
DOD
DOE
DSCR
EMAC
ESF#12
FEMA
FEMP
FIRM
FOMB
GDP
GMLC
GSA
ICS
INESI
IMT
IRP
ISAC
IT
LBNL
LCOE
LIPA
LNG
MATS
MSW
NARUC
NASEO
NEMA
NERC
NESC
NIST

Act for the Transformation and Energy Relief of Puerto Rico, 2014
Advanced Distribution Management Systems
Automated Information Sharing
Advanced Metering Infrastructure
Argonne National Laboratory
American Recovery and Reinvestment Act
Base Flood Elevation
Customer Average Interruption Duration Index
Combined Heat and Power
Contributions in Lieu of Taxes
Critical Infrastructure Protection
Congressional Research Service
Distributed Energy Resources
Distributed Energy Resource Management System
United States Department of Homeland Security
United States Department of Defense
United States Department of Energy
Debt Service Coverage Ratio
Emergency Management Assistance Compact
Emergency Support Function 12 – Energy
Federal Emergency Management Agency
Federal Energy Management Program
Flood Insurance Rate Map
Financial Oversight and Management Board
Gross Domestic Product
Grid Modernization Laboratory Consortium
General Services Administration
Incident Command System
Institute for Island Energy Sustainability
Incident Management Team
Integrated Resource Plan
Information Sharing and Analysis Center
Information Technology
Lawrence Berkeley National Laboratory
Levelized Cost of Electricity
Long Island Power Authority
Liquefied Natural Gas
Mercury and Air Toxins Standard
Municipal Solid Waste
National Association of Regulatory Utility Commissioners
National Association of State Energy Officials
National Electrical Manufacturers Association
North American Electric Reliability Corporation
National Electrical Safety Code
National Institute of Standards and Technology
2

 NOAA
NREL
NYPA
ORNL
OT
PMA
PREC
PREPA
PROMESA
PUC
PV
RMI
RPS
RSF
RUS
SAIDI
SAIFI
SNL
T&D
UPR
USACE
USDA
USGS
USVI
UTIER
W2E

National Oceanic and Atmospheric Administration
National Renewable Energy Laboratory
New York Power Authority
Oak Ridge National Laboratory
Operational Technology
Power Marketing Administration
Puerto Rico Energy Commission
Puerto Rico Electric Power Authority
Puerto Rico Oversight, Management, and Economic Stability Act
Public Utility Commission
Photovoltaic
Rocky Mountain Institute
Renewable Portfolio Standard
Recovery Support Function
Rural Utilities Service
System Average Interruption Duration Index
System Average Interruption Frequency Index
Sandia National Laboratory
Transmission and Distribution
University of Puerto Rico
United States Army Corps of Engineers
United States Department of Agriculture
United States Geological Survey
United States Virgin Island
Irrigation & Electrical Workers Union
Waste-to-Energy

3

 Table of Contents
Executive Summary ........................................................................................................................ 5
A. Introduction ................................................................................................................................ 9
A1. Purpose ................................................................................................................................. 9
A2. Existing Long-Term Recovery Visions and Principles...................................................... 10
A3. Recommendations for Immediate Action .......................................................................... 10
B. The Pre-Storm Condition of the Electricity System................................................................. 12
B1. Portfolio Considerations ..................................................................................................... 12
B2. System Performance ........................................................................................................... 12
B2A. Reducing Political Influences Over Infrastructure Decisions ..................................... 13
B3. Assumptions on Demand ................................................................................................... 14
B3A. Energy Efficiency and Demand Response ................................................................... 14
B3B. Infrastructure Interdependencies ................................................................................. 15
C. Recommendations by Subject Matter ...................................................................................... 18
C1. Transmission and Distribution ........................................................................................... 18
C1A. Context for Transmission Recommendations .............................................................. 19
C1B. Context for Distribution Recommendations ................................................................ 21
C1C. Substations ................................................................................................................... 22
C1D. Selective Segmentation ................................................................................................ 22
C2. Generation .......................................................................................................................... 24
C2A. Context for Generation Recommendations .................................................................. 25
C2B. Increases in Renewable Energy ................................................................................... 27
C3. Microgrids .......................................................................................................................... 29
C3A. Context for Microgrid Recommendations.................................................................... 30
C4. System Operations, Management, and Planning................................................................ 33
C4A. Context for Planning Improvement Recommendations ............................................... 34
C4B. Human Resources and Training .................................................................................. 40
C4C. Standards, Regulatory and Legislative Actions to Enhance Long-term Recovery ...... 40
D. Conclusion ............................................................................................................................... 42
Appendix A: Scenarios ................................................................................................................. 44
Appendix B: Consolidated Recommendations from Long-term Plans......................................... 47
Appendix C: DOE Recommended Actions .................................................................................. 54
Appendix D: Microgrid Tools ...................................................................................................... 58
4

 Executive Summary
The eye of Hurricane
Maria careened just
south of the United
States Virgin Island of
St. Croix in the early
hours of September 20,
2017, and landed in
Yabucoa, Puerto Rico,
shortly thereafter.
Arriving with maximum
winds just below the
threshold of category 5
intensity, the wind, rain,
and storm surge during
Maria’s eight hours over
Puerto Rico combined to
disrupt nearly all water,
electricity, and
telecommunications
services.

Figure 1: Hurricane Maria Making Landfall Over Puerto Rico
September 20, 2017 (Credit: NOAA; CIRA)

Hurricane Maria was the second strongest storm on record to hit Puerto Rico. 1 As of 8:00 PM
EDT on September 20, the Puerto Rico Electric Power Authority (PREPA) reported near 100%
of total customers in Puerto Rico without power, with the exception of facilities running on
generators. The outage threatened the health, safety, and economic wellbeing of the nearly 3.5
million U.S. citizens who inhabit the territory and further stressed the regional economy. A
recent report by the National Oceanographic and Atmospheric Administration (NOAA)
estimated that the monetary value of the total damage caused by Hurricane Maria in Puerto Rico
exceeded the next most costly hurricane to hit the Commonwealth by an order of magnitude. 2

1

1928 Okeechobee hurricane, also known as the San Felipe Segundo hurricane, was the strongest hurricane on
record to hit Puerto Rico.
2
NOAA, National Hurricane Center Tropical Cyclone Report: Hurricane Maria (Apr. 5, 2018)
https://www.nhc.noaa.gov/data/tcr/AL152017_Maria.pdf. This report estimates that the total damage to the
Commonwealth ranges from $65-115 billion.

5

 Figure 2: Sampling of Historic Hurricanes to Hit Puerto Rico (Credit: Sheila Murphy, USGS)

While this scale of restoration and recovery would challenge any community, Puerto Rico has
already faced economic and workforce issues which exacerbated the difficulty of restoration
efforts and dimmed the prospects of a quick recovery. Out-migration of skilled power engineers
and line workers, driven by a variety of factors, has accelerated in pace from 2010 through the
close of 2017, with more Puerto Ricans now living in the continental United States than in the
Commonwealth. The loss of human capital caused by this out-migration will further challenge
Puerto Rico’s ability to re-start its economy.
Despite such adversity, the people of Puerto Rico have shown tremendous strength and resilience
as they restore and rebuild their homes and communities. Leveraging the electricity grid to spur
economic growth in Puerto Rico’s various communities and economic sectors, including health
care, manufacturing, tourism, and agriculture, is essential to revitalization of the island.
Essential services from energy-enabled critical infrastructure including water, waste water,
waste, telecommunications, and transportation must be consistently and reliably operational to
support safety and health. Additionally, manufacturing and retail operations must be open and
employable to support economic wellbeing. A strong recovery and revitalization is important
not only to the region, but also to the United States as a whole.
Maintaining and enhancing the resilience of the electric grid at fair and reasonable costs can
provide service and value to Puerto Rican communities. Yet, no single investment in energy
6

 infrastructure at one point in time will achieve resilience. The energy infrastructure of Puerto
Rico must be designed, built, managed, and maintained in such a way to withstand
environmental and man-made disasters, ameliorate disruptions when they inevitably occur,
recover quickly, and incorporate lessons learned into post-event planning and operations. This is
a continual process of improvement, one involving a reassessment and adaptation of solutions
and technologies to address changing needs.
In support of those goals, this report contains resilience recommendations for the Government of
Puerto Rico to consider for incorporation into its recovery plans—including the plan specified by
Section 21210 of P.L. 115-123 (2018), and to provide useful insights for the disbursement of any
federal appropriations intended to rebuild or improve the energy infrastructure in the
Commonwealth of Puerto Rico. 3 Given the breadth of interdependencies across sectors,
assessment of potential alignment and sequencing of funding across different agency programs
that support various sector infrastructures would be beneficial. The report also notes where
additional analysis is needed to more precisely articulate resilience-related, investment-grade
suggestions regarding the design and specification of the electricity system in Puerto Rico.
Although additional analysis is necessary to further specify some of this report’s
recommendations that support resilience, recommendations that can be acted on today to
improve the performance of the system are as follows:
1. The Governor and PREPA should immediately ensure that updated, effective mutual aid
agreements and Incident Command System are primed to quickly provide support during the
next event.
2. The Puerto Rico Energy Commission (PREC) should coordinate a joint study with the Puerto
Rico Telecommunications Board to determine and enforce safe loading requirements of
distribution poles carrying both electric and telecommunications infrastructure.
3. Electricity transmission towers installed specifically for temporary emergency restoration
should be considered for prioritized replacement, potentially by monopoles. Many round
monopole structures withstood the storm effectively.
4. The PREC, in coordination with PREPA, should implement microgrid regulations in line
with accepted industry standards and practices; and establish effective, efficient, and
reasonable interconnection requirements and wheeling regulations. These regulations will
allow customers to design their systems in a manner that support the reliability and resilience
of the broader electricity grid.
5. The Puerto Rican State Office of Energy Policy or its successor, in coordination with other
appropriate Commonwealth agencies and instrumentalities, should immediately commence
drafting of an updated Energy Assurance Plan. This plan should provide for, among others,
the use of the Incident Command System including the immediate establishment of a
standing Incident Management Team.

3

For example, in early April the U.S. Department of Housing and Urban Development announced the largest single
amount of available Disaster Recovery Community Development Block Grant funds, including over $20 billion for
Puerto Rico and the U.S. Virgin Islands,
https://www.hud.gov/press/press_releases_media_advisories/HUD_No_18_028.

7

 Several recommendations require further analysis to fortify the recommendations; the analysis
should be conducted, to the extent practical, with the support and engagement of PREPA and the
Government of Puerto Rico, includes the following:
1. Power flow – assesses power system operations, including generator dynamics and
protective relay coordination [used to identify power system needs, evaluate technology
options, and help prioritize resilience investments, e.g., transmission enhancements]
2. Production cost and capacity expansion – informs economic dispatch strategies and longterm planning [used to understand how resource investments, system costs, and load are
impacted by key policy and technology sensitivities]
3. Microgrids, energy storage, and system segmentation – identifies where clusters of
generation and load provide maximum community benefit [used to identify prepositioning of
emergency generation, local hardening of infrastructure, and adjustment of emergency
procedures]
4. Infrastructure interdependencies – characterizes reciprocal relationships within the energy
sector (e.g., electricity-petroleum, electricity-LNG), as well as cross-sector infrastructure like
telecommunications and/or water [used to investigate supply disruption impacts and identify
mitigation approaches]
A summary of the DOE’s specific recommendations can be found in Appendix C.

8

 A. Introduction
A1. Purpose
This report contains recommendations for the Government of Puerto Rico to consider for
incorporation into its recovery plans, including the plan that Congress specified in Section 21210
of P.L. 115-123 (2018). 4 The recommendations reflect principles of resilience, 5 and are
intended to inform investments that use federal appropriations in the energy infrastructure in the
Commonwealth of Puerto Rico (hereafter “Commonwealth” or “Puerto Rico”). 6
These recommendations address some near-term actions and identify where further analysis is
needed to make more technically-informed investment decisions. The recommendations should
highlight where coordination across agencies and sectors may improve the resilience of
infrastructure in Puerto Rico. While each of the recommendations, if implemented, would
improve the resilience, a resilient energy system is not achieved through a single investment or
series of investments at a given time.
Rather, resilience results from an on-going focus on identifying and undertaking sound
investments, operating and maintenance procedures, and planning practices. Each of the
decisions in this iterative process should aim to enhance the ability of the system to withstand
likely stresses, ameliorate disruptions when they inevitably occur, recover quickly, and
incorporate lessons learned into post-event planning and operations.
This report is NOT a grid modernization roadmap or implementation strategy for Puerto Rico. It
recognizes that capital investment alone will likely be insufficient to achieve Puerto Rico’s goal
of an electric sector that is technically reliable, resilient, and affordable; after all, most
investments will have longer-term obligations associated with operations and maintenance costs.
Thus, success ultimately depends on the leadership and commitment of the Government of
Puerto Rico and entities such as PREC and PREPA to carefully identify Puerto Rico’s electricity
needs, assess the options, and make their own determination of a strategy that meets long term
goals and instills confidence for existing and new industries to invest on the island.

4

This section reads, in relevant part: “Not later than 180 days after the date of enactment of this subdivision and in
coordination with the Administrator of the Federal Emergency Management Agency, with support and contributions
from the Secretary of the Treasury, the Secretary of Energy, and other Federal agencies having responsibilities
defined under the National Disaster Recovery Framework, the Governor of the Commonwealth of Puerto Rico shall
submit to Congress a report describing the Commonwealth’s 12- and 24-month economic and disaster recovery plan
. . .”.
5
See, e.g., National Academies of Sciences, Engineering, and Medicine. 2017. Enhancing the Resilience of the
Nation's Electricity System. Washington, DC: The National Academies Press,
http://www8.nationalacademies.org/onpinews/newsitem.aspx?RecordID=24836.
6
Given the differences between the Commonwealth and the United States Virgin Islands (USVI), the USVI are not
addressed in this report. However, DOE staff and experts at the National Labs are working with their USVI
counterparts to improve resilience and reliability of the energy system for the benefit of the American citizens there.

9

 A2. Existing Long-Term Recovery Visions and Principles
On December 13, 2017, DOE convened experts from the community of public and private
energy stakeholders who had expressed interest in supporting the long-term recovery of Puerto
Rico (hereafter “December meeting”). The event stimulated continued dialogue on forming a
cohesive set of recommendations, based on the expert opinion of the varied stakeholders,
ensuring a strong technical rational for Puerto Rico’s energy investment decisions.
By the time of the December meeting, several participants had already issued their own vision,
roadmap, or recommendations for the restoration, recovery, and further modernization of the
Puerto Rican electricity grid. These publications varied greatly in their depth, detail, and scope.
A summary of these publications can be found in Appendix B.
All plans appeared to agree that modernization would serve recovery objectives, and all agreed
on the need to diversify and harden infrastructure against possible future disasters. Many
participants expressed the desire for a single vision for the future of Puerto Rico’s electricity
sector. The Commonwealth itself must establish that vision and ensure the appropriate
governance mechanisms are available to accurately reflect the needs of customers in that vision,
as well as guarantee accountability within the management of the energy sector to honor that
vision.
A3. Recommendations for Immediate Action
This report considered and integrated plans and materials from multiple resources. Many of the
recommendations in this report require further analysis to refine into investment-grade decisions.
However, while this analysis continues, the following recommendations can be acted upon today
to improve the performance of the electricity system:
1. The Governor and PREPA should immediately ensure that updated, effective mutual aid
agreements and Incident Command System are primed to quickly provide support during the
next event.
2. The Puerto Rico Energy Commission (PREC) should coordinate a joint study with the Puerto
Rico Telecommunications Board to determine and enforce safe loading requirements of
distribution poles carrying both electric and telecommunications infrastructure.
3. Electricity transmission towers installed specifically for temporary emergency restoration
should be considered for prioritized replacement, potentially by monopoles. Many round
monopole structures rode withstood the storm effectively.
4. The PREC, in coordination with PREPA, should implement microgrid regulations in line
with accepted industry standards and practices; and establish effective, efficient, and
reasonable interconnection requirements and wheeling regulations. These regulations will
allow customers to design their systems in a manner that support the reliability and resilience
of the broader electricity grid.
5. The Puerto Rican State Office of Energy Policy Office or its successor, in coordination with
other appropriate Commonwealth agencies and instrumentalities, should immediately
commence drafting of an updated Energy Assurance Plan. This plan should provide for,
among others, the use of the Incident Command System including the immediate
establishment of a standing Incident Management Team. Besides preparing for the next
hurricane season, moving immediately will leverage the local presence of utility industry
10

 response professionals working with PREPA and federal staff in the Joint Field Office.
Finally, the Southern States Energy Board may be able to facilitate peer-to-peer information
sharing and lessons learned from other states and utilities.

Figure 3: Expectations for the Grid (Source: LBNL) 7

7

https://emp.lbl.gov/sites/default/files/feur_9_webinar_value-added_services_20171106_fin.pdf.

11

 B. The Pre-Storm Condition of the Electricity System
B1. Portfolio Considerations
As became clear in the December meeting and subsequent discussions, four common goals recur
in discussions of the electricity system in Puerto Rico: 1) a reliable electricity supply, 2) with
consistent power quality, 3) at foreseeable and manageable cost, 4) that maximizes use of local
resources. These goals must be met under the constraints of underinvestment in an already aging
infrastructure, unimplemented legal requirements regarding improvements to electricity system
governance and investment decisions, and declining load.
B2. System Performance
This section will rely primarily on two PREC Orders and quote from them often. The first, Final
Resolution and Order PREPA Rate Review, was issued on January 10, 2017 in Docket CEPRAR-2015-0001 (“Rate Review Order”). 8 While this document contains a wealth of information
on PREPA’s system and operations, other documents in this docket, such as the Expert Reports
dated Nov. 23, 2016, are also full of information on these issues and comparisons to standard
practice in the states. The PREC summarized its findings of fact, conclusions of law, and
Commission Directives over pages 162-184. There are 120 Commission Directives regarding
improvements of PREPA’s system, operations, and legal compliance.
The second document, the Final Resolution and Order on the First Integrated Resource Plan for
PREPA (“IRP Order”) in docket CEPR-AR-2015-0002 is dated Sept. 26, 2016, shortly after the
passage of the Puerto Rico Oversight, Management, and Economic Stability Act (PROMESA).
In subject matter, it is less wide-ranging than the Rate Review Order, with its findings of fact and
conclusions of law on pages 93-101. It details the changes that will be made to PREPA’s system,
with a schedule and competitive bidding requirements for many items.
•

•

“PREPA’s officials and consultants describe an inefficient bureaucracy with high
absenteeism, overly staffed with non-value-added administrative personnel. Procedures for
budgeting and spending do not provide sufficient information on individual project plans and
completion. On major capital projects, PREPA was often unable to provide basic
explanations, work-plans, or other due diligence documentation.” Rate Review Order, p. 3
“PREPA’s own witnesses describe PREPA’s physical situation to be an ‘ailing grid,’
‘degraded infrastructure,’ and a ‘deteriorated’ transmission system.” Rate Review Order, p.
16

On another metric, PREPA’s forced outage factor of plants averaged 6.87% over 2010-15, but
ended that period at nearly 27%. Some units were completely out of service for extended periods
of time, while the best performing plant was fired by natural gas supplied by Gas Natural Fenosa,
majority owner of EcoEléctrica, achieving an availability rate of 97% and average capacity

8

http://energia.pr.gov/numero_orden/cepr-ap-2015-0001/.

12

 factor of 65%. Outage information is covered extensively in the Rate Review Order, over pages
65-72.
Three key metrics for electric system performance are System Average Interruption Duration
Index (SAIDI), System Average Interruption Frequency Index (SAIFI), and Customer Average
Interruption Duration Index (CAIDI). For background on these metrics and why they are
valuable, see “Tracking the Reliability of the U.S. Electric Power System: An Assessment of
Publicly Available Information Reported to State Public Utility Commissions” from Lawrence
Berkeley National Laboratory (LBNL). 9
During the period measured, PREPA’s SAIFI was calculated at 11.61, which is an order of
magnitude higher than the U.S. average. PREPA exceeded its SAIDI goal of 10 hours by 60%, a
goal which was above the75th percentile of U.S. utilities. PREPA’s CAIDI was 180 minutes, up
from 140 in 2013 - up nearly 30% since forbearance began. 10 The American Public Power
Association collects self-reported reliability data for publicly-owned utilities, “Evaluation of
Data Submitted in APPA’s 2013 Distribution System Reliability & Operations Survey.” 11
PREPA’s metrics exceed the averages and third quartile statistics for each of those categories.
B2A. Reducing Political Influences Over Infrastructure Decisions
Most energy reform legislation in Puerto Rico has sought to reduce the political influence over
PREPA’s decision-making, and the PREC addressed that topic as follows:
•

•

“The quadrennial turnover of managers with each new political administration, the political
pressures from elected officials to avoid necessary rate increases, the failure of government
agencies to pay their electricity bills on time, the irresponsible initiation and termination of
expensive capital projects, the high levels of electricity theft, the work rules that prevent
efficient use of well-paid employees, the poor recordkeeping and antiquated administrative
procedure, the compensation schemes that prevent PREPA from recruiting and retaining
qualified and experienced personnel – all this must come to a halt, to be replaced by a
universal commitment to the good of the Commonwealth.” Rate Review Order, pp. 23-24
“This situation is not sustainable. Until PREPA’s financial situation improves, it cannot
borrow new money. If it cannot borrow new money, 12 it cannot repair its deteriorating
physical infrastructure, prepare that infrastructure for a future of renewable energy, pay
salaries sufficient to attract and keep excellent workers, and modernize its system so as to
enable consumers to save money on their electric bills. The path to transforming PREPA into
a reliable, cost-effective, environmentally sound and customer-responsive company – a

9

https://emp.lbl.gov/sites/all/files/lbnl-1092e.pdf. See also, Institute of Electrical and Electronics Engineers, “IEEE
Benchmark Year 2016 Results for 2015 Data”, http://grouper.ieee.org/groups/td/dist/sd/doc/Benchmarking-Results2015.pdf.
10
"Final Resolution and Order: PREPA Rate Review," Docket CEPR-AR-2015-0001, dated January 10, 2017
(“Rate Review Order”), available on www.energia.pr.gov, p.18.
11
http://studylib.net/doc/18456145/2013-distribution-system-reliability-and-operations-report#.
12
PREPA entered Title III of the Puerto Rico Oversight, Management, and Economic Stability Act (PROMESA) in
April 2017.

13

 company central to Puerto Rico’s economic recovery – must begin with a plan for stabilizing
PREPA’s finances.” 13
B3. Assumptions on Demand
Before its economic crisis, the
population size of Puerto Rico was
comparable to Oregon, three times that
of Hawaii and five times that of Alaska.
Currently, its GDP per capita is lower
than any state. Similarly, while the
United States ranks near the top in the
World Bank’s “Doing Business”
metrics, Puerto Rico sits at 64. 14
Sustained economic hardship on the
island has accelerated the out migration
of citizens which had already resulted in
an estimated 500,000 people departing
Figure 4: Puerto Rico Economic Activity Index, from Government
for the mainland in the past decade.
Development Bank of Puerto Rico
Early estimates suggested
approximately 100,000 people have fled Puerto Rico since Hurricanes Irma and Maria hit. 15
Puerto Rico has five times the combined populations of the territories and Freely Associated
States. Although median income is comparable to the other insular areas, Puerto Rico has
maintained a manufacturing base, dependent in part on favorable treatment under the federal tax
code. As a consequence, the Puerto Rico energy system is larger than all of the others combined
by installed capacity.
In its pre-storm Fiscal Plan, PREPA predicts just over 13,000,000 MWh sales in 2026, roughly
equivalent to 1500MW average load and 2250MW peak. A similar number was released in the
Fiscal Plan from early 2018. Given that existing installed capacity exceeds 5,000MW, and the
existing transmission system was designed to accommodate this capacity, significant declines to
load in the next 10-15 years will be an important consideration for future investment plans.
These portfolio considerations underscore the need to further analyze power flow, production
cost, and other scenarios, to provide reasonable amount of certainty that any investments are well
targeted and integrated into cost-reflective tariffs to support an affordable and reliable power
system.
B3A. Energy Efficiency and Demand Response
As noted by the 2016 Congressional Task Force on Economic Growth in Puerto Rico, “The price
of electricity in Puerto Rico is high, while the ability of some residents of Puerto Rico—where
13

"Final Resolution and Order: PREPA Rate Review," Docket CEPR-AR-2015-0001, dated January 10, 2017
(“Rate Review Order”), available on www.energia.pr.gov, p.12.
14
The World Bank, Doing Business Economic Rankings, http://www.doingbusiness.org/rankings.
15
https://naturalresources.house.gov/calendar/eventsingle.aspx?EventID=403224.

14

 the median annual income is
$18,626—to pay is low.” 16 Energy
efficiency programs have short
lead times, can help optimize
capital expenditures, reduce the
need to import fuels, and alleviate
the energy burden on low income
households. 17 Demand response,
with its ability to shape load, can
limit the need for capital projects
with low utilization rates and limit
ramping stress on generators.
However, these benefits must be
balanced against the need for
other enabling infrastructure
requirements (e.g., communications upgrades).

Figure 5: Lead times for electricity projects (Source: LBNL)

Local law requires energy efficiency in building codes, improvements in government energy use,
reductions in subsidies to local government that distorts the cost of consumption, and the
promotion of cost effective end-use energy efficiency measures. The rapid conversion to Light
Emitting Diodes for public lighting, for example, has the potential to reduce the overall cost of
municipal lighting by up to 80%. For efficiency in public buildings, DOE’s Federal Energy
Management Program (FEMP) maintains expertise in Energy Savings Performance Contracts, a
procurement mechanism that requires little to no up-front capital. This is an area where resources
to establish effective training and enforcement of existing requirements may produce the system
benefits contemplated by local law.
B3B. Infrastructure Interdependencies
As was observed during Hurricane Maria, interdependencies among infrastructure systems with
electric power can cause cascading failures across various essential services. These dynamics are
not fully understood, and infrastructure planning does not yet effectively incorporate
interdependency considerations. It is also difficult to monetize the benefits associated with an
avoided disruption due to interdependency.
For example, during Hurricane Maria, the loss of cellular and data services in Puerto Rico was
sometimes a direct result of the power issues, not necessarily damage to the communications
infrastructure. In order to make efficient investments that mitigate risk effectively and increase
the resilience of Puerto Rico, capital planning decisions must address interdependencies between
the electric power system and other critical infrastructure that provide much needed services,
such as hospitals, water, waste water, waste, telecommunications, and transportation, to counter
16

Congressional Task Force on Economic Growth in Puerto Rico, “Bipartisan Report to the House and Senate”, p.
37 (Dec. 2016).
17
https://emp.lbl.gov/sites/default/files/feur_6_webinar_future_of_resource_planning.pdf.

15

 the cascading effects of power losses. A better understanding of the complex interactions among
critical infrastructure will help Puerto Rico prepare for, respond to, and recover from future
disasters.

Figure 6: Electric Power Interdependency Examples (Source: ANL)

To address interdependencies between electric power and other critical infrastructure, Puerto
Rico should conduct, with the engagement of federal agencies as appropriate, an analysis to
identify interdependencies and to help coordinate large-scale, regional infrastructure projects.
Furthermore, given the breadth of interdependencies across sectors, assessment of potential
alignment and sequencing of federal funding across different agency programs that support
various sector infrastructures, potentially across multiple areas of the islands including Puerto
Rico and U.S. Virgin Islands, would be beneficial. The analysis identified in this report will
support that goal.
B3Ba. Cyber-Resilience
As the electricity system grows in intelligence, the impact of malicious and unintentional cyber
threats has become an increasingly important issue for the electric sector. Electric utilities face
cyber threats to both the business and operational components of their outfits. The increased
automation of the electric grid has allowed grid operators to more efficiently and reliably
operate their networks. However, these same digital technologies have simultaneously
increased dependence on telecommunications networks and provided new avenues for cyber
adversaries to potentially gain control of operational components and disrupt electricity
service. 18
18

U.S. Department of Energy, Quadrennial Energy Review: Second Installment, January 2017,
https://www.energy.gov/epsa/quadrennial-energy-review-second-installment.

16

 Each utility must identify its own unique vulnerabilities and design mitigation options tailored
to its individual information technology (IT) and operational technology (OT) networks. This
can include taking concrete steps such as embedding cybersecurity in utility procurement
processes. 19 Additional actions can be informed by industry best practices as outlined in
frameworks including the National Institute of Standards and Technology’s (NIST) Framework
for Improving Critical Infrastructure Security, the North American Electric Reliability
Corporation’s (NERC) critical infrastructure protection (CIP) standards, and DOE’s Energy
Sector Cybersecurity Framework Implementation Guidance and Risk Management Process.
The Federal government uses an array of authorities and capabilities to prepare for, respond to
and mitigate cyber incidents that affect private networks. These include preparedness tools to
assist utilities in improving their cybersecurity posture, such as DOE’s Cybersecurity Capability
Maturity Model (C2M2), incident response support, and post-incident recovery assistance. DOE
has developed over 40 tools and technologies that can assist energy delivery providers to
mitigate, respond, and survive a cyber-attack. 20 Robust frameworks for information sharing
within and between the electricity industry and government are another critical resource for
ensuring the electric sector is able to mitigate the impact of cyber adversaries. A better
understanding of the complex interactions among critical infrastructure will help Puerto Rico
prepare for, respond to, and recover from future disasters.

19

https://energy.gov/sites/prod/files/2014/04/f15/CybersecProcurementLanguageEnergyDeliverySystems_040714_fin.pdf.
20
https://www.energy.gov/oe/cybersecurity-energy-delivery-systems-ceds-fact-sheets.

17

 C. Recommendations by Subject Matter
C1. Transmission and Distribution
RECOMMENDATIONS
1. Investments in grid improvements should be based on detailed modeling, such as load flow
modeling and contingency analysis, to identify the optimal resiliency and hardening benefits
for the transmission system. Re-routing transmission infrastructure does not now, in the
absence of analysis demonstrating its merit, present sufficient benefit to justify the cost. Load
flow and contingency analysis will reveal which lines should be re-routed to increase both
day-to-day reliability and resilience in the case of an event. This modeling will help rightsize and prioritize grid investments, which could otherwise have the potential to put
significant upward pressure on rates. 21
2. Recovery plans should provide for enhanced and enforced operations and maintenance to
mitigate the disruption caused by the next event. For example, guy wire anchors of
transmission infrastructure and static wire continuity need to be maintained to harden and
add resiliency. Other materials, such as stainless steel or composite anchors, may be needed
to replace some components at existing installations.
3. There are no recommended modifications to the current voltages associated with the
Transmission and Distribution (T&D) infrastructure as they are suitable for the current and
projected electrical needs of the island. However, a long term strategy to maintain
standardization with typical mainland voltage will help future mutual aid response.
4. USDA Rural Utilities Service (RUS) standards should be adopted where feasible and
appropriate to standardize equipment and design, which will aid with replacement in both
regular and emergency situations. USDA RUS standards govern the engineering and
component specification of all voltage ranges of electrical transmission and distribution
networks used by every rural electric utility in North America that borrows from RUS.
PREPA was an active RUS borrower until 2010, so restoring the power grid to meet
applicable RUS standards should be an attainable objective to prepare the utility for near
term emergencies and long term investments. Thus, as part of the reconstruction phase,
Puerto Rico’s grid should be restored, at a minimum, to RUS standards as well as other
applicable standards (e.g., NESC, NEC, NERC-CIP, NIST cybersecurity framework).
5. All replaced poles and towers should be of a design and material to survive 150 mph
sustained winds. If funds are available, electricity transmission towers installed specifically
for temporary emergency restoration after Hurricanes Irma and Maria should be considered
for replacement as soon as practicable, potentially by monopoles. Many round monopole
structures rode through the storm effectively.
6. The PREC should coordinate a joint study with the Puerto Rico Telecommunications Board
to determine and enforce safe loading requirements of distribution poles carrying both
electric and telecommunications infrastructure. Federal agencies can participate as necessary
and appropriate.
7. Implement industry best practices in a comprehensive vegetation management program to
protect the integrity of grid assets.

21

See Appendix A.

18

 8. Substation assets should be hardened, including transformers, circuit breakers, associated
switchgear, and especially control equipment, including protective relays and
communications gear. Revised Flood Insurance Rate Maps (FIRM) should be used to site
substation assets to avoid Base Flood Elevation (BFE) + 3.0 feet or 0.2% flood elevation,
whichever is higher. 22 In addition, siting should be outside of the floodplain whenever
possible and existing critical stations should be raised and/or waterproofed accordingly.
Besides relocation, detailed power system simulation will provide insights on which assets to
harden and in what priority.
9. Based on modeling results, strategic, judicious undergrounding of distribution lines should be
considered in limited appropriate circumstances. Based on experiences in Hurricanes Katrina
and Sandy, undergrounding of lines in coastal areas could present risk of salt-water intrusion;
other considerations are the depth of the island’s water table and subsurface rock. Any
underground distribution lines in a floodplain should conform to 10 CFR Part 1022.
10. For the benefit of both day-to-day and in-event scenarios, recovery plans should include a
strong modern Energy Management System, Remote Terminal Units, and other equipment
providing real-time information and control capability to utility operators. For example, AMI
for metering to serve as an operational tool providing real-time information that can, if
implemented appropriately, improve service to industrial customers and reduce non-technical
losses (caused by actions external to the power system such as theft) by enabling targeted
inspections of anomalous readings. Also, this intelligence could empower a predictive
maintenance program.
11. Analysis of the existing communication infrastructure available to support grid monitoring
and control functionality should be performed. This analysis would include: inventory and
document the existing fiber optic cable plant; research ownership of existing cables;
determine fiber connections and fiber terminations availability for secure utility applications;
analyze availability and functional performance and cybersecurity of the existing
communication termination equipment at the substations; identify suitable solutions to
support "last mile" communications to enable system monitoring and control functions,
sensors and other equipment; distribution automation, support; AMI data backhaul; and other
applications and functions.
12. Analysis should be conducted to determine the value of deliberate sectionalizing of the grid.
C1A. Context for Transmission Recommendations
There were failures in the transmission infrastructure resulting from the extreme winds (and
debris-driven entangling). Multiple transmission towers collapsed due to guy wire anchor rod
failures. The DOE field team postulates that anchor rod corrosion was the root cause of these
failures.

22

FEMA has acknowledged that storms exceed base flood elevation (BFE) levels, and that prudent design often
exceeds BFE levels [See FEMA’s 2013 publication: Designing for Flood Levels Above the BFE After Hurricane
Sandy]. While ‘FEMA 100-year flood plus three feet’ has been adopted as a design guideline for some utilities,
technical analysis should be conducted to assess the specific level of risk for Puerto Rico and utilities should
consider utilizing the 0.2% flood elevation as a resilience elevation.

19

 Notably, however, many of the “dead end” 23 structures that are
designed to limit the cascade of neighboring tower failures
performed as designed, thereby limiting the extent of the
damage to the overall transmission line infrastructure.
DOE assesses that the design of the transmission infrastructure
is fundamentally sound. However, DOE recommends an
enhanced program to mitigate corrosion of the guy wire anchor
rods, improved right-of-way maintenance for access to
structure locations, and updating of materials to more robust
industry standard components. Non-destructive evaluation
(NDE) inspection (i.e. ultrasonic) targeted by modeling and
analysis may prove particularly valuable to improving
reliability.
Furthermore, DOE recommends implementing a compliance
driven vegetation management program to remove
encroachment of taller vegetation and danger trees from the
rights-of-way.
Many of the transmission lines were originally routed through
difficult-to-access mountainous terrain. Subsequently, new
roads crossing these mountain areas have been constructed.
Therefore, the opportunity exists to consider building new
transmission corridors along these roads that would facilitate
better vegetation management access, as well as quicker access
by heavy equipment to repair damaged infrastructure during
future storm events. The DOE recommends that these new
transmission lines be considered based on an assessment of
overall system requirements based on detailed modeling and
engineering studies. However, re-routing transmission
infrastructure does not, in the absence of analysis
demonstrating its merit, present sufficient benefit to justify the
cost.
Finally, the DOE team assesses that the current voltages
associated with the T&D infrastructure (230 kV for the
backbone transmission infrastructure, with supporting 115 kV
transmission infrastructure and lower voltage sub-transmission
assets) is suitable for the current and projected electrical needs

Pole Attachment & Wind
Loading Standards
Best practices for third-party
(e.g., communication)
infrastructure attachments to
power system distribution
infrastructure includes both
clearance and structural
assessments to confirm
compliance with applicable safety
codes (including specifically the
National Electrical Safety Code)
to assess safe clearances are
maintained between energized
and non-energized cables on each
structure and above the ground
surface below. This also includes
an assessment to ensure that the
structural integrity is maintained
to support the increase in vertical
and wind load to each structure.
Therefore, DOE recommends that
the utility establish, manage, and
maintain a joint-use program that
sets criteria for third-party
attachments to verify required
clearances are maintained and
structural integrity is maintained
as required by the applicable
safety codes.

23

https://en.wikipedia.org/wiki/Dead-end_tower. A dead-end tower is a fully self-supporting structure used in
construction of overhead power lines. Since dead-end towers require more material and are heavier and costlier than
suspension towers, it is uneconomic to build a line with only self-supporting structures. Dead-end towers are used at
regular intervals in a transmission line to limit the cascading tower failures that might occur after a conductor
failure.

20

 of the island. It is anticipated that these voltages would continue to be in common use by U.S.
electric utilities in the foreseeable future. Therefore, design and accessibility to equipment should
be readily available. Standardization using typical mainland voltage will help future mutual aid
response.

C1B. Context for Distribution Recommendations
There were significant failures in the distribution infrastructure, including many failed wood
poles. The DOE assessment of these failures concludes that many of these failures were likely
caused by overloading caused by communication system attachments to these poles. The DOE
team is uncertain to the extent that the communication industry providers were required to
conduct structural loading assessments of these attachments.
The DOE team also surmises that there was deferred maintenance associated with testing the
integrity of the poles associated with the distribution infrastructure. DOE recommends that
PREPA follow industry best practices for a comprehensive testing program to identify and
replace wood poles that are in need of replacement. In addition, there should be careful
consideration of cost-effective alternatives to wood as a material for distribution poles. Possible
wood alternatives could include 3D printing/additive manufacturing of poles designed with
desired characteristics to endure Puerto Rico’s unique conditions.
The DOE assesses that enhanced vegetation management would have been a decisive factor
limiting the extent of the damage to the distribution infrastructure. This is a common theme that
has plagued the electricity industry for many years. Over the past few decades, there has been
significant progress in industry practices associated with vegetation management for utility
infrastructure. DOE recommends that PREPA follow industry best practices for a comprehensive
vegetation management program to protect the integrity of their distribution assets, particularly
during extreme weather events.
Some examples of these best industry practices 24 include:
Routine Maintenance
•
•
•

Most utilities trim trees back 10 feet from the circuit in accordance with National Electrical
Safety Code (NESC) standards.
While it is not possible to trim trees for hurricanes, the elimination of overhangs and
subsequent tree fall-ins on lines must be a priority and goes a long way toward eliminating
tree-related outages.
It is imperative to have consistent and adequate financial resources to carry out the vegetation
management mission. The underlying problem is that vegetation management budgets are
easy to cut when the utility faces budgetary issues, so it is crucial to get the company board’s
approval for a vegetation management program that meets well-defined specifications.

24

https://bear.warrington.ufl.edu/centers/purc/docs//presentations/events/hurricanehardening/R0507_PURC_Report_on_the.pdf.

21

 •
•

When engaged in tree trimming, it is imperative to follow tree trimming standards such as
ANSI A300 standards, to the greatest extent possible.
Continuity of tree trimming crews ensures consistent, high quality and adherence to
standards in vegetation management for the utility and its customers.
Restoration

•
•
•
•

Coordinate vegetation management and debris removal with line work so tree crews stay
ahead of line crews in the process.
Assign a grounding crew to accompany several tree crews in case tree clearance requires
lines and facilities be grounded if necessary.
With regard to line crews being brought in from out of the service territory, have readily
available pre-printed or electronic material (maps, procedures, FIRMs, etc.) and easy to
complete paperwork and documentation.
There is also likely tree damage that has not affected lines during the storm but may affect
lines well after the storm. Extra crews should patrol and clear potentially dangerous timber
and limbs before causing damage to existing lines.

C1C. Substations
The DOE team observed that several substations were flooded (both salt water in coastal areas
affected by storm surge, and fresh water associated with rainfall induced flooding). The DOE
team recommends that the newly revised FIRMs be studied and that substation assets found
within flood areas are re-sited to avoid these areas, or raised and/or waterproofed accordingly
using flood-resistant materials, and anchors as required to survive these events. 25 In addition to
avoiding these areas, recommendations are to raise substations to the 0.2% flood elevation if
possible. This is particularly important for key substations that are deemed essential to the
reliability of the overall T&D infrastructure or associated with key generating assets.
These aforementioned substation assets need to include transformers, circuit breakers, associated
switchgear, and especially control equipment including protective relays and communications
gear. The New York Power Authority (NYPA) has extensive experience in this area and
provided recommendations for substation improvements. 26 See Appendix B.

C1D. Selective Segmentation
To better enable system recovery and/or black start restoration, there might be operational
benefits for segmenting the transmission system into smaller portions. While this would be done
25

FEMA P-348, Protecting Building Utility Systems from Flood Damage. February 29, 2017,
https://www.fema.gov/media-library-data/1489005878535-dcc4b360f5c7eb7285acb2e206792312/FEMA_P348_508.pdf.
26
New York Power Authority, et al., Build Back Better: Reimagining and Strengthening the Power Grid of Puerto
Rico, December 2017, New York Power Authority,
https://www.governor.ny.gov/sites/governor.ny.gov/files/atoms/files/PRERWG_Report_PR_Grid_Resiliency_Repo
rt.pdf.

22

 out of necessity following a large-scale event, there could be some advantages to pre-selecting
which segments are likely able to survive a future event, and proactively plan for segmenting the
transmission system accordingly. These portions of the system would be identified to include a
mix of generating assets, including black-start capable units, along with appropriately sized load,
so that when the distribution system is undergoing restoration activities, and enough load would
be present to constitute minimum generation capabilities, stable portions of the system could be
energized and maintained prior to the longer transmission lines being repaired and energized.
These portions of the system could then be re-energized with each other later in the restoration
process.
A key enabler of this technology is synchrophasor technology, which provides a timesynchronized measurement of both the magnitude and phase angle of voltages across the
network. This enables independent synchronous islands within the overall system to operate
independently, and can also facilitate re-synchronization as assets are restored.
Another benefit of pre-planning this segmented mode of system operation is coordinating the
protection and control systems. Under normal system conditions, protective relay coordination
makes necessary assumptions about available fault current, and the protection settings are
coordinated to provide the appropriate balance between speed and selectivity. However, during
an emergency, quickly and effectively developing new protection settings may be difficult;
having a pre-planned system segmentation strategy could greatly enhance the overall restoration
timeline. The preplanned segmentation can be activated in preparation for emergency operations
in anticipation of storms or other emergencies.
Implementing this idea requires analyzing the available clusters of generation and load, including
a realistic assessment of the robustness and flexibility of the various generation sources. Priority
loads would then be identified, and T&D pathways connecting these generations with these loads
would be assessed. Then an operational plan for selective segmentation would be characterized
to proactively separate into these segments, thus reducing the exposure to damage and increasing
the likelihood of maintaining survivability of localized energized subsystems. If a segment
requires full black-start restoration, those plans would be optimized for each individual segment,
with the associated protection and controls in place to more quickly enable that recovery.

23

 C2. Generation
RECOMMENDATIONS
1. Evaluate the siting of key generation
facilities so that, to the extent
practicable, they are co-located with
key load centers to reduce the
criticality of the transmission system
when recovering from anticipated
extreme events in the future. In
particular, analysis on re-powering
Palo Seco with alternative fossil fuels
is recommended.
2. Ensure the generation mix complies
with all relevant legal and regulatory
requirements, both local and Federal.
Preliminary analysis shows that
moving toward a more diverse fuel
portfolio, including alternative fossil
fuels, renewable energy and energy
Figure 7: Existing Generation Mix and Energy Consumption
efficiency, will produce significant cost
in Puerto Rico [Pre-storm]
reductions. Fuel-efficient load(Source: NREL - https://www.nrel.gov/docs/fy15osti/62708.pdf)
following combustion turbines could
greatly improve fuel efficiency as compared to conventional steam turbine power plants.
However, as with grid infrastructure, detailed modeling, such as production cost, capacity
expansion analysis and detailed machine modeling, can help determine the best course of
action to integrating new generation sources for Puerto Rico.
3. Given PREPA’s pre-storm estimated sales in 2026, as few as three of PREPA’s current
power plants may satisfy estimated load in ten years, when combined with purchased power.
Any hardening efforts should focus on those plants, including the Costa Sur power plant. As
other facilities are retrofitted, especially Palo Seco, to comply with Mercury and Air Toxic
Standards (MATS) and other relevant legal requirements, detailed hardening assessments
should be undertaken.
4. Evaluate the extent to which integrating small and flexible generation assets near load centers
into a more intelligent system could reduce the number of critical failure points.
5. While much of PREPA’s generation that was operational before the storm was not
significantly compromised by Hurricanes Irma or Maria, a program of hardening generation
assets would ensure continued resilience to weather events, beginning with critical central
plants regardless of ownership. The current excess of generation affords the opportunity to
model energy interdependencies and assess fuel contingencies, including shipping concerns,
source of fuels, storage locations, and the impact of disruption and emergency response.
Analysis can indicate where to prioritize dual fuel generation capability and sufficient levels
of on-site fuel storage.

24

 C2A. Context for Generation Recommendations
A variety of legal requirements, some Federal and most local, will prompt significant changes to
the fuel portfolio, operations, and costs of operating the electricity system in Puerto Rico. In
particular, the electricity system must evolve to reduce the dependence on imported fuels; and
comply with local laws regarding central station efficiency, the energy mix, end-use energy
efficiency, and environmental law requirements.
Preliminary analysis, summarized in Appendix A, indicates that these changes to the generation
portfolio have the potential to reduce fuel expenditures by 10% compared to business as usual,
with a similar reduction to Levelized Cost of Electricity (LCOE). Preliminary analysis also
shows that right-sizing investment in the grid is equally important to controlling the overall cost
of the system.
In part because of favorable economic forecasts related to natural gas, displacing oil imports with
U.S. natural gas has been one of the explicit goals of Puerto Rico energy sector reform. In its
report, the Bipartisan
Congressional Task Force stated:
Electricity System Assets
“Few, if any, observers question
the conventional wisdom that
• 4,878 MW of Generation Owned by PREPA
Puerto Rico should take steps to
o >90% Capacity Uses Heavy Fuel Oil
reduce its disproportionate reliance
• 2,416 Miles of Transmission
on petroleum and increase its use
• 30,675 Miles of Distribution
of natural gas—of which the
• 334 Substations
United States is now the world’s
• 961 MW of Independent Power Production
largest producer—and renewable
o Natural Gas, Coal, Hydro, Wind, and Solar
energy sources like solar power if
economically viable.”
Puerto Rico already has one natural gas import terminal, supplying a power plant called
EcoEléctrica, supplied by gas from Trinidad & Tobago and other international markets. Bringing
more natural gas into Puerto Rico will require the expansion of the import capacity at
EcoEléctrica and/or the construction of another import terminal. The original design and
permitting for EcoEléctrica would allow it to expand to import more Liquefied Natural Gas
(LNG), but would require a pipeline along the southern coast to Aguirre power plant or a
pipeline through the mountains to San Juan. Both of these pipelines have been pursued in the
recent past, but both were halted or cancelled. 27 In lieu of a pipeline to Aguirre, whose access to
the Caribbean is interrupted by a marine preserve, the Roosevelt Roads Redevelopment area
could provide a large enough brownfield to accommodate a new gas import terminal and power
plant.
In order to increase the use of natural gas from the United States, and thereby reduce foreign fuel
imports, the gas must be transported in compliance with the Jones Act, overseen by the Maritime
Administration of the Department of Transportation. There are currently no Jones Act compliant
27

A former senior official at PREPA testified that “the cancellation of the south gas pipeline in 2009 was not
optimal”, Rate Review Order, p. 79.

25

 vessels available to deliver large volumes of U.S. LNG to Puerto Rico. There may be no
capacity at U.S. shipyards to build a Jones Act compliant ship for LNG transport before the mid2020s. In addition to large volumes of LNG, smaller volumes of LNG could be transported to
Puerto Rico in ISO containers. DOE is aware of at least one company that provided small-scale
LNG shipments to Puerto Rico earlier this year.
As generation infrastructure is modernized, the flexibility that modern equipment fired by
alternative fossil fuels becomes a critical characteristic. According to an international partnership
between the Electric Power Research Institute, International Energy Agency, National
Renewable Energy Laboratory (NREL), and others, “Flexibility can also reduce overall system
costs and consumer prices, via more efficient power system operation. Flexibility might also
improve environmental impacts of power system operations via increased optimization of
demand response, more efficient use of transmission, and reduced renewable curtailments.” 28
As stated above, modeling will help identify the optimal size, location, and fuel type of
generation assets. This additional analysis could inform the level of federal support needed to
complement private sector investment. Given PREPA’s pre-storm estimated sales in 2026, as
few as three of PREPA’s current power plants may satisfy load in ten years, when combined
with purchased power. Any hardening efforts should focus on those plants, including the LNGfired Costa Sur plant. As other facilities are retrofitted to comply with MATS and other relevant
legal requirements, detailed hardening assessments should be undertaken.
In addition, solar PV and energy efficiency enjoy short lead times relative to other energy
infrastructure projects, and so have the potential to realize recovery benefits more quickly.
Energy storage can provide valuable ancillary services to the grid, and complement the
renewable energy generation required by local law.

28

21st Century Power Partnership, “Flexibility in 21st Century Power Systems” (2014),
http://www.nrel.gov/docs/fy14osti/61721.pdf.

26

 Turning Disaster into Opportunity for a Resilient Community in Greensburg
On May 4, 2007, a tornado destroyed or damaged 95% of the homes and businesses in
Greensburg, Kansas. The town turned disaster into opportunity and created a plan to rebuild
as a sustainable community with the help of the U.S. Department of Energy (DOE) and the
National Renewable Energy Laboratory (NREL), among others. For three years, DOE and
NREL experts worked with city leaders, business owners, residents, and other state, federal,
and local agencies to identify ways to incorporate energy efficiency and renewable energy
technologies into the town's rebuilding efforts. Through energy modeling, education,
training, and onsite assistance, DOE and NREL helped renovate and rebuild homes in
Greensburg that, on average, use 40% less energy than similar buildings built to code—
surpassing the 30% energy savings goal the town originally set. The town of Greensburg
focused on rebuilding to Leadership in Energy and Environmental Design (LEED)
certifications, achieving many “firsts” for the country and the state of Kansas, including:
•
•
•

The first LEED Platinum municipal building in the state
The first LEED Platinum critical access hospital in the United States
The first residential LEED Platinum building in Kansas

Greensburg also installed solar PV and wind energy turbines to take advantage of local
renewable resources.

C2B. Increases in Renewable Energy
In order to meet legal requirements regarding the transition away from heavy fuel oil, local law
requires 20% of sales to be supplied by renewable energy by 2035, indicating approximately
1200 MW of renewable electricity capacity. Using PREPA’s pre- and post-storm load forecasts,
average daily load will be approximately 2000MW. Thus, by another metric like capacity, the
current Renewable Portfolio Standard (RPS) target of sales would translate to an ambitious but
still achievable goal. 29
The delivered cost of electricity from independent renewable power producers, from PPAs
signed in 2014, compared favorably with the cost of PREPA’s heavy fuel oil-fired plants. The
cost of renewable technology has decreased, and the knowledge of how to integrate these
technologies into the grid has increased, in the intervening years.

29

The Hawaiian Electric Companies delivered renewable electricity amounting to 27% of sales in 2017.
https://www.hawaiianelectric.com/clean-energy-hawaii/clean-energy-facts.

27

 Figure 8: Electricity Price Comparison (Source: DOE, EERE)

Puerto Rico has no fossil fuel or geothermal resources available locally. The University of Puerto
Rico (UPR) conducted an analysis of the technical potential of several renewable resources,
concluding that the potential renewable resources available to Puerto Rico – including wind,
solar, hydro, and biomass resources – could provide large amounts of energy to the island. A
narrower study from NREL indicated using brownfield sites for solar photovoltaic (PV) would
provide economic power from potentially contaminated land.

Figure 9: Renewable Energy Potential (Source: DOE)

Puerto Rico has traditional biomass resources, and could explore the feasibility of importing
biomass pellets from the Southeastern U.S., especially as the AES coal-fired plant license is set
to expire in the next ten years. Another alternative fuel source available locally is Municipal
Solid Waste (MSW). Most of the active 29 landfills in Puerto Rico are beyond capacity, and the
U.S. Environmental Protection Agency (EPA) has reached agreements to close twelve of them.
Each of those twelve agreements includes a recycling program, creating the feedstock sorting
infrastructure that can facilitate Waste-to-Energy (W2E). W2E can reduce the amount of waste
headed to a landfill and generate electricity; an evaluation of W2E in the U.S. Virgin Islands
indicated favorable economics including the cost of limited environmental mitigation. While in

28

 use in the U.S., W2E technology, and anaerobic digestion in particular, is a common waste
treatment solution in Europe.
A recent study by NREL used an existing solar PV plant in Puerto Rico to provide frequency
response and other grid support services for PREPA’s grid. Using existing infrastructure, the
study showed, on an actual system, how renewable energy can be effectively and efficiently
integrated into PREPA’s system – and outperform traditional operational practices. That same
study showed this to work in Texas, and a similar study showed this to work in California.
Another study, by Sandia National Laboratory, showed how distributed PV can be operated as a
virtual power plant on a small grid to provide certain grid support services more cost effectively
than traditional operations.
Finally, the energy storage that can be used to complement variable renewable generators have
been shown to provide black start capability for natural gas turbines, 30 indicating that a holistic
view of these assets can identify different optimal configurations than were available in the
twentieth century. As the electricity system in Puerto Rico transitions towards a modern grid, it
will be important to ensure these kinds of contributions are considered toward any minimum
renewable power requirements.
As part of the 2015 IRP process, PREPA estimated that 322MW of distributed solar will come
online through 2035, supplying approximately 17% of the legally required minimum of
renewable electricity. This private investment in distributed generation will be facilitated if clear
expectations regarding interconnection and remuneration are set and adhered to consistently by
all relevant parties.

C3. Microgrids
RECOMMENDATIONS
1. Recovery plans should include analysis to determine the potential applicability and optimal
locations for microgrids, including their specialized role in the system (e.g., serving critical
infrastructure in urban areas, serving unique needs of industrial customers, or serving remote
communities). This analysis should include the availability of generation resources, fuels,
load type, and the boundaries of microgrids.
2. Microgrid designs should rely on a suite of existing tools (e.g., DER-CAM, and the
Microgrid Design Tool – see Appendix D) to help design and value microgrids, once their
location(s) has been identified.
3. Communities that have required generator assets for extended periods of time should
consider microgrids and the potential to leverage temporary generation that has been in
service over the past few months.

30

Imperial Irrigation District in California used a 33MW/20MWh battery to black start a 44MW combined cycle
natural gas turbine in 2016.

29

 4. Analysis as part of the recovery plan should consider and evaluate different pathways to
contain grid failures during future events, and the different roles of transmission
sectionalization and microgrids in providing reliability and resilience.
5. Interdependencies between electric power and other key sectors, specifically water, waste
water, waste, telecommunications, transportation, and public health and safety, should be
assessed and considered when infrastructure funding decisions are made. Potential alignment
and sequencing of federal funding across different agency programs that support various
sector infrastructures, possibly across multiple areas of the islands would be beneficial. The
analysis identified in this report will support that goal.
6. Microgrids may prove effective at ensuring the availability of critical services during an
event. Analysis can help prioritize critical infrastructure for hardening, for example, through
a critical infrastructure resiliency bank.

C3A. Context for Microgrid Recommendations
There are two types of microgrids: grid-tied and remote. Grid-tied microgrids can run in parallel
with the grid or remain islanded for a certain duration of time. The key feature is that these
microgrids have access points to the grid which are connected. Grid-tied microgrids vary
significantly in size and sophistication, while remote microgrids serve small isolated populations
often not served by the main grid.
DOE defines microgrids as follows: "A group of interconnected loads and distributed energy
resources (DER) within clearly defined electrical boundaries that act as a single controllable
entity with respect to the grid. A microgrid can connect and disconnect from the grid to enable it
to operate in both grid-connected and island mode. A remote microgrid is a variation of a
microgrid that operates in island conditions" 31
The DOE team observed that recovery for remote mountainous communities was significantly
delayed compared with the more densely populated areas associated with major metropolitan
areas. DOE believes that there is an opportunity for distributed generation and energy storage,
deployed in microgrids, to provide resilience enhancement to these communities. While there is
economic and reliability value in being connected to the PREPA system during normal
conditions, storm recovery and community support can be enhanced through these communitybased microgrids in more remote areas of the Commonwealth. In addition, while further analysis
is required before developing specific recommendations, microgrid investment has the potential
to be more cost effective than alternative system upgrades to harden the system for improved
function and reliability.

31

For example, a stand-alone DER such as solar, wind, CHP, or energy storage, without a controller or islanding
capability would not meet this definition; it must be a larger set of loads and resources combined with controls that
operate as a system. IEEE p2030.7 Standard for the Specification of Microgrid Controllers and the language of IEEE
p1547-REV and IEEE 1547.4 for islanded systems should be followed.

30

 The services that microgrids can provide vary greatly to support different applications, such as
critical infrastructure availability, industrial site reliability, and basic service in remote areas.
Microgrids can facilitate the integration of distributed energy resources, which will help to place
generation assets close to loads and diversify fuels, as recommended in Section C2 (Generation)
of this report. In addition, microgrids may be able to offer benefits to the PREPA grid (like
power and ancillary services). In order to maximize the benefits of each microgrid, it will need
to be designed for its specific site, use, and suite of benefits and should be at least as resilient as
the grid.
Increasing Reliability of Industrial Infrastructure in Louisville
Oak Ridge National Laboratory (ORNL), in partnership with Sandia National Laboratories
(SNL) and UPS, assessed microgrid capabilities at the UPS WorldPort facility in
Louisville, Kentucky - the most technically advanced facility of its kind in the world. UPS
is very interested in the development of an industrial microgrid to serve their 50MW peak
WorldPort facility to increase reliability and strengthen the surrounding grid through
advanced microgrid control schemes. At the WorldPort facility, even short outages can
cost millions of dollars; a microgrid system will help to eliminate this risk. In addition, the
microgrid assets will provide benefits during “blue-sky days” such as demand reduction
and utility services. ORNL, SNL, and UPS are investigating the risks, costs, and benefits of
a microgrid at the UPS WorldPort and Centennial Hub facilities. The “Industrial Microgrid
Analysis and Design for Energy Security and Resiliency” project provides a roadmap for
UPS and other industries interested in microgrid technologies by laying out the technical,
institutional, and regulatory challenges associated with developing an industrial microgrid.
It will also highlight the interaction between an industrial customer interested in pursuing a
microgrid and the customer’s utility.

The physical and economic interaction between microgrids and the main grid need to be
examined. These applications need to be identified in the context of the overall system, whether
critical loads and/or areas least able to withstand disruptions or remote end-of-line areas.
Modeling and power-flow analysis from the transmission substation to the microgrid or local
customer may assist in prioritizing projects. PREC and PREPA should allocate interconnection
costs and risks, as well as tariffs that recognize beneficial ancillary services provided by
customer owned microgrids.

31

 Distribution System
Aspects

Integration API

Transmission
Modeling

Check if resiliency and
economic impact improved
because of microgrids by
assessing the impact

Microgrid Site Modeling

Geospatial Map
Visualization

Microgrid Roll-Out Plan
and Prioritization Map

Figure 10: Potential Approach for Microgrid Deployment (Source: ANL)

Modeling and analysis will contribute to the identification of the most advantageous potential
microgrid locations. Three main applications of microgrid technology have been discussed that
would be beneficial for Puerto Rico. These applications include essential services/critical
infrastructure in urban areas; unique needs of certain customers, such as large or clustered
industrial customers; and remote locations and the islands of Vieques and Culebra. 32
When considering locational issues, the microgrid system needs to provide a certain load serving
capability over a given duration of time without fuel supplies from outside the microgrid
boundary. This requires the analysis of load to serve critical infrastructure. The Microgrid
Design Tool (MDT), 33 DER-CAM, 34 and OpenDSS can be employed to assist with this analysis
(See Appendix D).
As more DERs and microgrids are deployed, PREC should consider adopting standards relevant
to the Puerto Rico network, ensuring that project developers have a clear and unambiguous
32

In April 2018, PREPA announced a request for proposal seeking providers of power solutions for the electrical
system of the island municipalities of Vieques and Culebra.
33
http://energy.sandia.gov/download-sandias-microgrid-design-toolkit-mdt/.
34
https://building-microgrid.lbl.gov/projects/der-cam.

32

 understanding of the requirements needed for compliant projects. The electric power industry
has adopted and continues to refine standards for distributed energy and microgrid systems. The
Institute of Electrical and Electronics Engineers (IEEE) has developed IEEE 1547 and 2030
Standards for Distributed Energy Resources (DER) Interconnection and Interoperability with the
Electricity Grid (including IEEE 2030.7-2017: Approved Draft Standard for the Specification of
Microgrid Controllers, and 2030.8: Draft Standard for the Testing of Microgrid Controllers). The
North American Electric Reliability Corporation (NERC) also has developed industrial standards
for the interconnection of DER and microgrids.

Strengthening Community Resilience in New Orleans
Since the devastation of Hurricane Katrina, resilience has been a renewed focus for New
Orleans. Through the Grid Modernization Initiative, the U.S. Department of Energy
worked with researchers from Sandia and Los Alamos National Laboratories and city
officials to strengthen New Orleans’ resilience to natural disasters. The “Grid Analysis and
Design for Energy and Infrastructure Resiliency for New Orleans” project in 2015-16
developed a set of cost-effective options for enhancing resilience. Their recommendations
focused on advanced microgrids, automated reclosers and automated fault location,
isolation, system recovery (FLISR) software, as well as localized backup generation. The
team identified clusters of high-impact infrastructure, like emergency medical services and
fuel stations and fleets, assets could be best served by microgrids during a blackout or
other disruption. By ensuring a reliable “Plan B” for such critical infrastructure, services
could be returned to citizens much faster than if they are dependent on power being
restored to the larger grid network.
Prior to the more detailed engineering studies, the DOE’s Energy Transition Initiative and
National Labs delivered recommendations in the form of conceptual designs for New
Orleans officials, Entergy, and state and federal agencies to rank energy infrastructure
improvement options and set improvement implementation and funding priorities. The
project produced approaches and lessons learned that can be applied to other cities across
the nation including Puerto Rico and the U.S. Virgin Islands.
C4. System Operations, Management, and Planning
RECOMMENDATIONS
1. Training and capacity building, particularly on asset management, system planning, and data
collection should be supported as a part of all infrastructure expenditures, including
Integrated Resource Planning, Energy Assurance Planning, and cost of service accounting.
2. PREPA, PREC, and other Commonwealth agencies and instrumentalities should be
resourced to draft and execute staff training plans as part of expenditures on infrastructure.
To the extent necessary, PREPA should identify skills gaps within its technical and
33

 3.

4.
5.

6.

7.

engineering staffs, and identify whether other groups (such as Administrative and General)
are right-sized to forecasted sales and engineering needs.
The recovery plan should call on the utility to identify a core team responsible for IRP
submissions and other regulatory affairs, set aside sufficient resources for their work and data
collection, and utilize additional training from relevant national organizations.
The Puerto Rican State Office of Energy Policy or its successor should immediately draft an
updated Energy Assurance Plan, which should be reviewed on an annual basis.
Ensure that any and all funded projects are consistent with approved and vetted long-term
plans that provide reasonable assurances of compliance with all local and federal laws and
regulations.
The Governor and PREPA should update mutual aid agreements to facilitate the rapid
sharing of emergency aid and resources and ensure that Incident Command Systems are
primed to quickly provide support during the next event.
Consider additional legislation and regulation that may improve reliability and resiliency
including, without limitation: regulations that prescribe design and installation standards for
all T&D towers and poles to withstand 150 mph wind speed, regardless of material; all
critical electricity system assets should be located at BFE + 3 feet or the 0.2% flood
elevation, whichever is higher, or sited outside the flood plain entirely, if possible (see note
in Section C1 of this report); and an annual review of the Energy Assurance Plan, and all
associated components, including mutual assistance agreements, and technical and logistical
procedures for Incident Management Teams. To the extent feasible in order to enhance
operational efficiencies and interoperability, regulatory agencies should consider and adopt
relevant NERC reliability standards to be implemented by the Commonwealth.

C4A. Context for Planning Improvement Recommendations
C4A1. Integrated Resource Planning
Puerto Rico became the first U.S. territory required to conduct forward-looking planning with
the Act for the Transformation and Energy Relief of Puerto Rico, 2014 (Act 57) including
comprehensive oversight of the process by a local regulatory body. 35 PREC approved the first
Integrated Resource Plan (IRP) for Puerto Rico on February 10, 2017. 36 Both Act 57 and the
PREC regulation on the IRP process, “Regulation on the Integrated Resource Plan for the Puerto
Rico Electric Power Authority” (May 22, 2015), require specific items to be addressed in the
IRP.
The process began with Act 57, which requires that the utility periodically develop and submit to
the PREC for review, an integrated resource plan. Section 6.23 of Act 57 states:
(a) PREPA…shall submit to the Commission an Integrated Resource Plan (IRP)
describing the combination of energy supply and conservation resources that satisfies in
the short-, medium-, and long-term the present and future needs of the energy system
35

Act 57-2014, Act for the Transformation and Energy Relief of Puerto Rico, May 2014 (Act 57),
http://www.oslpr.org/download/en/2014/A-057-2014.pdf.
36
Resolution on the Verified Motion for Reconsideration of the Puerto Rico Electric Power Authority, CEPR-AP0002-15.

34

 both of Puerto Rico and of their customers at lowest cost possible. . .. (d) After the
approval of the integrated resource plans, the Commission shall supervise and oversee
compliance therewith. Every three (3) years, the Commission shall carry out another
review process, and if applicable, modify such plans, as well as issue and post on its
website, a detailed report showing compliance with integrated resource plans and the
modifications made thereto after the review process.
The IRP Order and Rate Review Order, issued by the PREC, identified the many ways PREPA’s
energy infrastructure can be improved. Puerto Rico law also provides for contractual
arrangement with outside parties with the expertise needed to modernize PREPA’s infrastructure
and improve its performance. Attracting outside expertise may result in novel, reliable, lower
cost solutions to meet the energy needs of Puerto Rico.
C4A1a. The Key Role of the Puerto Rico Energy Commission
The energy regulatory authority in Puerto Rico, equivalent to a state Public Utilities
Commission, was created by Act 57. At the time of passage, several states regulated aspects of
rate setting or other behaviors of publicly-owned electric utilities. 37 While there is often variance
between the scope of state-level regulation of municipal utilities and investor-owned utilities,
one example that may prove to be of particular relevance to Puerto Rico is the change to the
Long Island Power Authority’s (LIPA) autonomy in 2013, whose debt restructuring plans have
resulted in investment-grade ratings by both S&P and Moody’s. 38
Similar to the legislative reforms of LIPA, Act 57 subjected PREPA to a state-level regulatory
authority, the PREC. Beyond the reforms in New York, Act 57 made several other strides in
creating an energy system governance structure that is standard in the fifty states. These
included: 1) establish the PREC; 2) establish a consumer advocate; 3) establish a long-term
planning process, called the “Integrated Resource Plan” (“IRP”); 4) ensure certain levels of
efficiency in the generation fleet; 5) promote end-use efficiency, including in the public sector;
6) promote diversity and reliability in the fuel portfolio; 7) focus the efforts of the state energy
office; 8) enable the functional separation of generation and grid services; and 9) reform certain
long-standing consumption subsidies, including those paid to municipal governments. 39
Stepping into this environment of policy modernization, the newly-established PREC was
empowered with regulatory authority to implement many of the reforms described in Act 57, as
well as less comprehensive but still significant reform efforts from the preceding years. 40 With

37

American Public Power Association, “References for State Rate Regulation of Public Power Utilities” (June 19,
2014), http://appanet.files.cms-plus.com/Resources/Rate_reg_of_PP_by_PUC_-_Statutes_6_19_2014_update.pdf.
38
https://www.lipower.org/wp-content/uploads/2016/09/SP-Global-Ratings-Report-LIPA-20171122.pdf;
https://www.lipower.org/wp-content/uploads/2016/09/LIPA-Report-Moodys-2017-2.pdf.
39
The full, 165-page Act 57 is here: http://www.oslpr.org/download/en/2014/A-057-2014.pdf. A more detailed
summary is available from a Puerto Rico law firm: http://www.mcvpr.com/media/publication/273_Act%2057.pdf.
40
Of note, Acts 82 and 83 of 2010, enabling wheeling of electricity and setting a Renewable Portfolio Standard,
among other changes.

35

 further refinements in the Electric Power Authority Revitalization Act, 2016 (Act 4), the PREC
began operations with the scope and power typical of any state PUC. 41
Among them, the PREC was created with explicit jurisdiction over planning as part of landmark
energy reform designed to bring Puerto Rico’s energy system governance in line with state best
practices, as well as increase the fuel diversity, efficiency, and overall performance of the energy
system in Puerto Rico. As the PREC has noted, “the center-stage of the energy reform [is]
turning back years of fiscal and operational mismanagement.” 42
PROMESA 503(b)(1)(D) also calls for reliance on the PREC’s IRP process. This deference to
the local process was reaffirmed by the Congressional Task Force on Economic Growth in
Puerto Rico in 2016. It stated: “There are certain challenges in Puerto Rico—such as an outdated
energy system, a troubled K-12 public education system, and inefficiencies in various other
sectors—that must be tackled first and foremost by the government of Puerto Rico and the
private sector.” 43
In May 2015, the PREC finalized a 41-page order, the Regulation on Integrated Resource Plan
for the Puerto Rico Energy Power Authority, which included, among other points, specific
requirements as to information and analytic requirements, and performance metric targets. 44
PREPA submitted its IRP in July 2015, which was rejected by PREC, who requested a modified
IRP. PREPA submitted its modified IRP in February 2017, but after review, the PREC found the
plan insufficient, stating:
The IRP provided by PREPA was insufficient in terms of the process and mechanisms
chosen for achieving the results contained therein. Therefore, the Commission is unable
to rely upon the IRP filed by PREPA. If the IRP cannot be used for its intended purposes,
then it is noncompliant. 45
The above timeline is not unusual, but PREC was highly critical of PREPA’s plan, and the
utility’s responsiveness. And given the significant changes resulting from the September 2017
hurricanes and restoration efforts, the PREC has revised the timeline for future submissions:
The Commission finds that a review of PREPA’s existing IRP (the February 2017
Modified IRP) prior to the three-year term established in The Puerto Rico Electric Power
41

http://www.oslpr.org/download/en/2016/A-004-2016.pdf.
Final Order on PREPA’s Motion for Reconsideration, p. 9 (Mar. 7, 2017), http://energia.pr.gov/wpcontent/uploads/2017/03/8-marzo-2017-Final-Resolution-PREPAs-Reconsideration-CEPR-AP-2015-0001.pdf.
43
Congressional Task Force on Economic Growth in Puerto Rico, “Report to the House and Senate”, p. 8 (Dec.
2016).
44
Commonwealth of Puerto Rico, “Regulation on Integrated Resource Plan for the Puerto Rico Energy Power
Authority,” Puerto Rico Energy Commission, May 22, 2015, http://cepr.cloudapp.net/wpcontent/uploads/2015/09/RE-8594-EN.pdf.
45
PREPA’s first IRP was disapproved by PREC in September 2016. PREC allowed for a revised IRP. PREC
statement from: Commonwealth of Puerto Rico, “IRP for PREPA: Resolution on the Verified Motion for
Reconsideration of the Puerto Rico Electric Power Authority,” Puerto Rico Energy Commission, Case No. CEPRAP-2015-0002, February 10, 2017, http://energia.pr.gov/wp-content/uploads/2017/02/10-feb-2017-ResolutionRuling-on-PREPAs-Verified-Motion-for-Reconsideration.pdf.
42

36

 Authority Act, 1941 (Act 83) and Act 57 is warranted in order to determine the effects
hurricanes Irma and Maria may have had on Puerto Rico’s resource needs and determine
whether any proposed update, revision or modification is necessary to mitigate
“substantial changes in demand or group of resources….The Commission authorizes
PREPA to file an updated IRP on or about October 2018. 46
C4A1b. The Role of the PREPA Governing Board
Under its original act (Act 83), as amended, PREPA’s internal controls are overseen by a
Governing Board. Until Act 57, six of nine members were appointed by the Governor with the
advice and consent of the Senate, and a seventh served ex officio, by virtue of appointment to an
executive branch position by the governor. No qualifications were explicitly required, and no
conflict of interest restrictions on service were made explicit.
Act 4 further refined the responsibilities of PREPA’s Governing Board. It eliminated the ex
officio positions and returned the Governor’s appointments to six of nine, with the key
distinctions that those individuals must: 1) be selected from a list compiled by an executive
search firm “based on objective criteria” including expertise, and 2) meet the criteria of
independence set by the New York Stock Exchange Corporate Governance Standards. Also, Act
57 restricted on service for persons with “substantial economic interest” in PREPA’s business
decisions, similar to the standard practice of ensuring diversity and independence for Boards of
Directors in privately-owned corporations. Nonetheless, Act 3-2017 provides that every member
of a governing board or body of a public corporation, like PREPA, shall enjoy the trust of the
Governor of Puerto Rico. The Governor may remove a member who is believed to have failed to
implement his public policy or who has lost his trust to carry out the fiscal plan to be submitted
to the Financial Oversight and Management Board. The statute provides that the Chief of Staff
and cabinet members in a committee shall make recommendations to the Governor as to who
should be removed for such reasons. 47
PREPA’s governing body was further reformed by Act 37-2017 to a full composition of seven
(7) members. The Governor shall appoint three (3) of the seven (7) members from a list of
candidates with educational and professional background in fields such as: electrical engineering,
business administration, economics and finance, or law, and no less than ten (10) years of
experience in the field. Also, they shall have expertise in energy affairs and shall not be public
employees, except for being professors at the University of Puerto Rico. The independent
members and the elected member shall be subject to the independence requirements under the
NYSE Corporate Governance Standards. The statute also calls for review of the Board’s
compliance with industry’s governance standards every three (3) years by a recognized
consultant with expertise and experience in providing advice to boards of directors of similar
entities. 48

46
Government of Puerto Rico Energy Commission, March 15, 2018, CEPR-AP-2018-0001, “Commencement of
Review Proceeding and Order Establishing Initial Submission Timeline,” http://energia.pr.gov/wpcontent/uploads/2018/03/Resolution-and-Order-IRP-CEPR-AP-2018-0001.pdf.
47
http://www.oslpr.org/download/en/2017/A-003-2017.pdf.
48
http://www.oslpr.org/download/en/2017/A-037-2017.pdf.

37

 As of March 2018, the PREPA Board approved the issuance of a Request for Proposals (RFP)
for the development of a new IRP. 49
C4A1c. The Role of the PREPA Executive Director
Act 4 also refined the role and responsibilities of PREPA’s Executive Director, giving the Board
discretion to dismiss the person serving, rather than requiring cause. This change is another
incorporation of standard practice in private industry to help ensure effective and efficient
management.
C4A2. Energy Assurance Planning and Mutual Aid
Another critical form of planning in the energy sector is energy assurance planning. Energy
infrastructure and delivery systems are increasingly vulnerable to severe weather, system, and
infrastructure failures, and deliberate physical or cyber-attacks. Planning for energy sector
disruptions—termed energy assurance planning, and often led by a Governor’s energy office—is
essential to safeguarding energy system reliability and resilience. Energy assurance planning can
help to achieve a robust, secure and reliable energy infrastructure that is also able to restore
services rapidly in the event of any disaster. 50
Energy providers can respond quickly to limited disruptions. Spikes in energy demand during
peak energy use, unanticipated power plant or refinery outages, transmission congestion, or
natural disasters can cause disruptions that extend over a broad area or last more than several
hours. These energy emergencies often require intervention by government emergency
responders and a more collaborative public-private response to ensure public health and safety.
Government officials can coordinate across governments (federal, state and territory, local) and
government agencies and with utilities and other energy providers, businesses, and the public to
reduce consequences and provide for rapid recovery. Governments should be in ongoing contact
with industry, always seeking ways to reduce risk and vulnerabilities to critical energy
infrastructure to reduce the effects of future disruptions.
Nearly all state and territory governments and select local governments have an energy assurance
plan, which serves as a foundation for action when an energy disruption threatens public welfare
or when the energy industry requests help. These plans address energy supply risks and
vulnerabilities and enable a quick recovery and restoration. Combined with training and
exercises for personnel and stakeholders, energy assurance plans enhance response and recovery
efforts and support resiliency investments.
DOE has provided support for states and local governments to develop and refine energy
assurance plans, build in-house expertise on infrastructure interdependencies (i.e., other critical
infrastructure systems’ reliance on electricity for operations) and vulnerabilities, and integrate
renewable energy portfolios and new applications such as cyber and smart grid technologies. The
energy assurance plan that DOE has on file for Puerto Rico is from 2011.

49
50

https://www.aeepr.com/docs/irp%20rfp%2020180310%20.pdf.
NASEO, Energy Assurance Planning, http://www.naseo.org/energyassurance.

38

 As demonstrated by post-Hurricane restoration efforts in Puerto Rico, a lack of replacement parts
and back-up equipment can delay restoration efforts. Energy assurance plans ensure that state
officials, in collaboration with industry, consider the development of an inventory and identify
the proper placement of essential components and back-up equipment to operate the energy
system. Given Puerto Rico's geography and the delays associated with shipping resources to the
island, this aspect of an energy assurance plan should be an important and early focus.
Under the direction of the DOE’s Office of Electricity (OE), the National Association of State
Energy Officials (NASEO) and the National Association of Regulatory Utility Commissioners
(NARUC) created guidelines 51 for states and territories to use in the development of energy
assurance plans. The guidelines integrate lessons learned from prior energy emergencies and
energy emergency exercises of government and industry officials. The National Emergency
Management Association (NEMA) also offers a helpful and related resource on current state and
promising practices for energy assurance planning. 52
Puerto Rico is a member of the Emergency Management Assistance Compact (EMAC), a
national interstate mutual aid agreement that enables states to share resources during times of
disaster. (EMAC is administered by NEMA, the National Emergency Management Association.)
The thirteen articles of the Compact set the foundation for sharing resources from state to state. 53
In the response to Hurricane Maria, the six-week delay in requesting mutual aid assistance
hampered recovery efforts and raised questions as to Puerto Rico authorities’ overall
management of the recovery effort. While no regulatory changes are needed, a complete review
of the procedures for invoking a call for mutual aid assistance should be undertaken to ensure
future situations are handled effectively.
To prepare for the future calling for mutual aid assistance, the utility, along with appropriate
Commonwealth government agencies, should undertake a review of their emergency response
management procedures and develop an updated Incident Command System (ICS). In general,
ICSs are part of the National Incident Management System (NIMS) under federal Department of
Homeland Security authority.
An ICS establishes a command hierarchy to coordinate emergency response and identifies the
Incident Management Team (IMT) and procedures for communications, use of emergency
equipment (and pre-positioning), and command operations.
Many U.S. East Coast utilities adopted or upgraded their ICS procedures in 2012 following
Superstorm Sandy. PREPA and appropriate Puerto Rico authorities can expedite their ICS
update by working with utilities (such as members of the Southern States Energy Board) and
with utility organizations, such as the American Public Power Association (APPA). Beyond
51

NASEO, Guidelines, http://www.naseo.org/eaguidelines.
NEMA's Energy Assurance Planning: Current State and Promising Practices,
https://www.nemaweb.org/index.php/docman/resources/long-term-power-outage/919-nema-energy-resiliencereport-oct-2017/file?force-download=1.
53
Emergency Management Assistance Compact, at https://www.emacweb.org/index.php.
52

39

 developing plans and an organization structure, it is important that PREPA and appropriate
Puerto Rico authorities conduct periodic training exercises based on their ICS.
C4B. Human Resources and Training
Consistent with the overall economic decline in Puerto Rico and the resulting outmigration, the
grid-related workforce has shrunk by over 30% over the past decade. 54 Thus, DOE agrees with
the recommendations of the NYPA report that future re-building efforts should provide
opportunities for the retention of on-island skilled labor and development of new high-quality
jobs. And that highly skilled (or re-trained) technicians will be needed to operate future
systems—e.g., control centers enabling active monitoring and control of distributed generation
and microgrids; enhanced outage management functionality, integrated with an Advanced
Distribution Management Systems (ADMS) and Distributed Energy Resource Management
Systems (DERMS); and integrated cyber and physical asset security in all systems. 55
Furthermore, training staff to comply with ISO certification could help ensure resources are
allocated to capture the full value of the initial capital expenditures.
In 2015, the University of Puerto Rico created an interdisciplinary program called the Institute
for Island Energy Sustainability (INESI). As one of its first major projects, INESI received a
National Science Foundation grant to study the technical and social barriers to a highly
distributed energy future in Puerto Rico. In conjunction with federal recovery and mitigation
efforts, INESI could provide the foundation on which to firmly establish Puerto Rico as a Center
of Excellence on distributed grid operations, and could provide both the supply of
interdisciplinary engineers and policymakers Puerto Rico will need and the expertise other island
and remote grid systems will need in their transition to a distributed, resilient electricity sector.
DOE recommends that the PREC be properly staffed, with a sufficient number of professionals
skilled in the appropriate technical areas, so that the review of plans—e.g., IRPs, EAPs—is as
effective and efficient as possible. Periodic training for PREC staff would help ensure that they
are kept abreast of industry best practices.
C4C. Standards, Regulatory and Legislative Actions to Enhance Long-term Recovery
A number of the recommendations presented earlier in this report may require regulatory or
legislative changes to be implemented effectively. DOE identifies those changes in this section.
Earlier recommendations called for all transmission and distribution towers and poles to be
designed and installed to withstand 150 mph wind speed standard, and for critical grid assets to
be located at least 3 feet above (in elevation) the line demarcated by the revised FEMA FIRMs.
Legislative and/or regulatory action will be needed to ensure these standards are adhered to and
effectively implemented. NERC reliability standards may guide similar standard setting tailored

54

2,343 PREPA employee retirements since 2012, 1,018 were from T&D operations and 630 were from generation
operations. PREPA Draft Fiscal Plan 04 2-18 and Rate Review Order, pp. 37 and 51-52.
55
NY Power Authority, et al., Build Back Better: Reimagining and Strengthening the Power Grid of Puerto Rico,
December 2017.

40

 to Puerto Rico, and provide for penalty provisions for non-compliance to be enforced by the
Commonwealth. 56 This may require legislative action.
In Section C4B, DOE discussed the need for comprehensive Energy Assurance Planning (EAP)
in conjunction with mutual assistance projects. A comprehensive plan that addressed technical
issues as well as logistical issues, such as the lodging of external technicians, should be
periodically updated and practiced using live-action drills. Legislative action may be necessary
to affect an annual review of the Energy Assurance Plan and mutual assistance agreements, as
well as resources to practice those plans in drills. The plans and exercises should engage large
energy customers in the Commonwealth to ensure the adequacy of the EAP. DOE, as well as the
National Association of State Energy Officials, can provide assistance in the development of
EAP activities.

56

The North American Electric Reliability Corporation (NERC) is a not-for-profit entity set up to ensure the
reliability of the electricity system in North America. NERC sets mandatory and enforceable industry standards
under the authority delegated by the Federal Energy Regulatory Commission (FERC). This authority allows NERC
to assess penalties on electric utilities and service providers that fall out of compliance with relevant standards.

41

 D. Conclusion
The analysis needed to provide the system-wide understanding for resilience investment is being
undertaken with all due haste.
The fundamental question that modeling and analysis must answer, in collaboration with the
Government of Puerto Rico and PREPA, is which design options will provide the people of
Puerto Rico with the resilience they need and the downward pressure on rates critical to the
Commonwealth’s economic revitalization. The insights gathered from these efforts will allow
articulation of firm recommendations on a variety of investment decisions that will confront the
Commonwealth.
The recommendations included here are intended to inform recovery plans pursuant to section
21210 of P.L. 115-123. DOE observed that, generally, PREPA designed the electricity system
well, as evidenced by the uncompromised power stations and effective “dead end” structures. It
became clear that the system was weakened over time to the point of catastrophic failure, in the
face of the second most powerful hurricane to hit the Commonwealth in recorded history.
The recommendations focus on what considerations should be incorporated into the recovery
plan required by Section 21210 of P.L. 115-123. The recommendations focus on three main
areas:
1. Ensuring that investments will result in modern, intelligent infrastructure systems that are
affordable, reliable, and resilient, while fully complying will all local and federal law;
2. Undertaking the analysis and planning necessary to de-risk those investments and identify an
effective mix of centralized and distributed energy resources of different fuel types; and
3. Providing for adequate training and capacity building to offset human capital out-migration
and transitioning system operations.
In addition, as soon as practicable, DOE recommends that:
1. The Governor and PREPA should immediately ensure that updated, effective mutual aid
agreements and Incident Command System are primed to quickly provide support during the
next event.
2. PREC should coordinate a joint study with the Puerto Rico Telecommunications Board to
determine and enforce safe loading requirements of distribution poles carrying both electric
and telecommunications infrastructure.
3. Electricity transmission towers installed specifically for temporary emergency restoration
should be considered for prioritized replacement, potentially by monopoles. Many round
monopole structures withstood the storm effectively.
4. The PREC, in coordination with PREPA, should implement microgrid regulations in line
with accepted industry standards and practices; and establish effective, efficient, and
reasonable interconnection requirements and wheeling regulations. These regulations will
allow customers to design their systems in a manner that supports the reliability and
resilience of the broader electricity grid.
42

 5. The Puerto Rican State Office of Energy Policy or its successor, in coordination with other
appropriate Commonwealth agencies and instrumentalities, should immediately commence
drafting of an updated Energy Assurance Plan. This plan should provide for, among other
things, the use of the Incident Command System including the immediate establishment of a
standing Incident Management Team.
Even before the storm, there was “consensus that the high cost and low reliability of electric
power in Puerto Rico is one of the most serious challenges confronting households and
businesses, and a significant obstacle to economic growth on the island.” 57 The
recommendations and analysis identified in this report should guide any recovery plans for
energy infrastructure in Puerto Rico toward creating a modern, intelligent energy sector that can
be the engine for Puerto Rico’s revitalization.

57

Bipartisan Congressional Task Force on Economic Growth in Puerto Rico, p. 37
https://www.finance.senate.gov/imo/media/doc/Bipartisan%20Congressional%20Task%20Force%20on%20Econom
ic%20Growth%20in%20Puerto%20Rico%20Releases%20Final%20Report.pdf.

43

 Appendix A: Scenarios
MATS Waiver
LCOE in 2035,
Relative to BAU 58
assuming $1bn
Grid Investment
Relative LCOE
for $5bn Grid
Investment
Total Portfolio
Cost $1bn Grid
Investment
Total Portfolio
Cost High Grid
Fuel Saved
Consumer Energy
Efficiency

2025 Compliance

2035 Compliance

Baseline

-16.0%

-10.9%

+7.1%

-8.5%

-3.5%

Baseline

-21.5%

-17.3%

+7%

-14.4%

-10.4%

Baseline

$11,234,097,575.73
5,149,461MWh Saved
through 2035

$9,014,097,706.74
5,149,461MWh Saved
through 2035

N/A

Costs and capacity factors came primarily from the most recent publicly-available figures from
the Energy Information Administration. More relevant capacity factors for Puerto Rico power
plants were taken from the Fortieth Engineer’s report for existing power plants. NREL and
LBNL offer more granular cost and capacity factor information for solar PV and wind,
respectively, enabling a broader range of inputs to reflect the size of projects in Puerto Rico
relative to the U.S. mainland. These figures were held constant across each scenario to provide a
basis for comparing difference in the overall cost of the different systems through 2035.

The Business-as-Usual (BAU) Scenario assumes Puerto Rico continues operating its heavy fuel
oil units subject to MATS as currently applied for existing generation, pre-storm renewable
energy is restored, and distributed generation reaches 322MW by 2035.

The 2025 Compliance Scenario and 2035 Compliance Scenarios assume that the electricity
system meets all relevant legal requirements by 2025 and 2035, respectively, including:
•

Mercury and Air Toxics Standards and Act 57 High Efficiency Generation requirements met
by -o Re-firing Palo Seco with propane,
o Maintaining the LNG-fired EcoEléctrica and Costa Sur,

58

This chart sets the LCOE for the BAU $1bn Grid Investment scenario as equal to 1, so that the LCOE for other
scenarios is shown as a percentage change away from BAU and low grid investment.

44

 •

•

o Expanding LNG import capacity at EcoEléctrica to supply a completed southern pipeline
that fires 500-600MW of new combined cycle gas turbines at Aguirre or Roosevelt
Roads,
o Co-firing biomass at AES;
Energy efficiency equal to 1.5% of retail electricity sales annually, as a result of requirements
regarding:
o Building energy codes,
o Energy Savings Performance Contracts in government-owned buildings,
o Streetlight retrofits to Light Emitting Diodes (LEDs),
o Ratepayer-funded consumer end use efficiency program,
o Reductions in technical and non-technical losses;
Renewable energy sufficient to meet the existing RPS, met by –
o Restoring pre-storm utility-scale projects,
o Each project currently before the Revitalization Coordinator,
o 322MW of distributed solar, per PREPA’s estimate,
o 100MW of existing hydro facilities that need refurbishment,
o 150MW of biomass,
o 150MW of solar,
o 25MW of wind.

45

 Puerto Rico 2015 IRP MATS Waiver Energy Distribution

0%

0 ns hore Wind



Solar residential roofs

Solar commercial roofs

Solar utility scale

lFuel Oil

lCoal

LNG

 

PR Legal Compliance Energy Distribution

Biomass
Onshore Wind
20% I Hydro
Solar residential roofs
Solar commercial roofs
Solar - utility scale
I Municipal Solid Waste
2% - Fuel on
I Coal
19% LNG
New Propane near San

Juan 
Expand LNG at eXIstIng
port: US fuel

 

16%

46

Appendix B: Consolidated Recommendations from Long-term Plans
All plans issued to date, explicitly mentioned the need for transmission and distribution
infrastructure improvements. Plans consistently recommended hardening transmission and
distribution systems for increased storm resilience, with recommendations ranging from Rocky
Mountain Institute’s (RMI) specific proposed step of updating grid ties to New York Power
Authority’s (NYPA) wide-scale recommendation to relocate substations and upgrade relay
protection to enable DER and microgrid integration. DOE proposed repairing where needed and
replacing to hardened specifications. NYPA, Congressional Research Service (CRS), and FEMA
all recommended relocating lines or reducing distribution line lengths to reduce their risk from
weather events.
Financial Oversight and Management Board (FOMB), PREPA, DOE, NYPA, and CRS all
recommended increasing the grid’s “smart” capabilities, including automation and scalability.
These plans also recommended updating the control systems used across the grid, noting the
importance of this step, in light of each plan’s suggestion to add renewable generation sources
that introduce variability into energy supply. NYPA specifically recommended two-way
communication systems such as ADMS and DERMS, which they noted are key for demand
matching. DOE, CRS, and FOMB suggested adding more robust sensing and control capabilities
to better locate and respond to issues when they arise. DOE specifically called out the need for
these new communication and controls systems to be cybersecure, as well as the need to identify
and mitigate other risks inherent to information and communications technologies.
Multiple plans made recommendations for the overall Puerto Rican electricity system to be
designed and operated for enhanced resilience through the incorporation of new technologies,
including behind-the-meter distributed generation and other energy resources as well as
technologies that could reduce or adjust loads such as energy efficiency. The PREPA, FOMB,
and RMI plans also recommended re-thinking system architecture, including moving generation
assets to be closer to load as well as building regionalized grids. The DOE, NYPA, and CRS
plans all discussed the incorporation of microgrids and energy storage and the strategic use of
DERs to help balance loads. DOE also proposed additional interconnection arrangements
between municipalities to enhance community resilience, while CRS proposed the potential
development of interconnections with the U.S. Virgin Islands and other Caribbean islands for
load balancing and to reduce the need for back-up power. Multiple plans recommended the
adoption of best practices for system operations, including sound long-term planning (PREPA),
practicing storm readiness (CRS), and modernizing control center facilities and adding mobile
backup control centers (NYPA).
Not all plans specifically addressed the institutional or market elements of Puerto Rico’s power
grid, but those that did all called for some type of reform. Proposed reforms varied, but a
common theme was overhauling managerial and financial arrangements to increase transparency
and rationalize annual operating costs and rate structures. Federalization was recommended in
the DOE and CRS reports as a means of governance, though alternatives such as municipality
ownership, co-ops, and public-private partnerships were also considered. The DOE, CRS, and
47

 RMI plans promoted strengthening the role of the independent regulator to ensure transparent,
accountable, and enforceable regulation, while both the PREPA and FOMB plans promoted
privatization to drive investment. The PREPA plan highlighted five key pillars that needed to be
upheld by any governing structure: customer-centricity, financial viability, reliability and
resilience, sustainability, and service as an economic growth engine for Puerto Rico.
Most plans recommended consumer engagement through the implementation of energy
efficiency programs, the promotion of energy efficiency practices, or by providing choices for
behind-the-meter efficiency. The DOE and NYPA plans also emphasized the importance of
enforcing building energy codes, especially for new buildings constructed post-hurricane.
A majority of plans touched on environmental concerns, with DOE, RMI, and PREPA reports in
particular noting the reduction in emissions and air pollution associated with diverse energy
resources and renewable generation; the RMI plan also specifically called out the consumer
benefits of lowered air pollution and CO2 emissions. In order to be fully prepared for future
events, the CRS plan recommended robust hardening of areas likely to be most impacted by
worsening climate change.
Most plans proposed long-term timelines for recovery and modernization, with each of DOE,
NYPA, and CRS outlining a 9-10-year schedule. The RMI and PREPA plans focused on slightly
more near-term actions, while the FEMA plan prioritized immediate, disaster-response activities.

48

 Comparison and Characterization of PR Recovery Plans as of April 30 2018
DOE 59

Electricity Sector
Approach

Generation

Fuel Mix

Ensure standard
management and
oversight practices
are enforced

NYPA 60

Restoration,
upgrade to best
practices, harden,
grid modernization

Modify the size and
technology of fleet,
potentially reduce
reserve margin for
PREPA

CRS 61

Harden
infrastructure,
modernize power
system

RMI 62

FEMA 63

Reinvestment
strategy to
support a more
resilient, costeffective, and
sustainable grid

Restore
critical,
restore
general
population,
harden,
modernize

PROMESA 64

PREPA 65

Transparent
Privatization with a
management,
model for power
incentivize private generation and delivery
investment, and
that sets a global
develop “bias for
example for cost,
action” to begin
resilience,
integrating various
sustainability, and
resources towards customer engagement
broad end-state
and empowerment.

Update location
and technology
of generating
assets

Move away from
More renewable
Increase share
Less carbon intensive,
fuel oil and towards
Revisit the 2015
energy integration,
Less volatile mix
of generation
increasingly take
U.S. natural gas and IRP to incorporate
though wind and
Diesel
(divest
capacity from
advantage of renewable
renewable energy shift to natural gas,
solar potential
generators diesel, bunker and
"fuel-free
power generation
resources (wind,
increased DERs,
limited. Need to
used
coal), 50%
energy
alternatives and
solar, hydro,
and hardening of consider alternatives,
immediately
renewables by
resources" (RE,
integrate emerging
biomass, and wasteexisting assets
including hydro, fuel
2040
EE)
technologies
to-energy)
cells, and storage

59

B. Parks et al., Catalyzing an Innovative, Resilient, and Secure Electric Sector for Puerto Rico, U.S. Department of Energy, November 2017.
New York Power Authority, et al., Build Back Better: Reimagining and Strengthening the Power Grid of Puerto Rico, December 2017, New York Power
Authority, https://www.governor.ny.gov/sites/governor.ny.gov/files/atoms/files/PRERWG_Report_PR_Grid_Resiliency_Report.pdf.
61
Richard J Campbell, Corrie E. Clark, and D. Andrew Austin, Repair or Rebuild: Options for Electric Power in Puerto Rico, Congressional Research Service,
November 16, 2017, https://fas.org/sgp/crs/row/R45023.pdf.
62
Isaac Toussi and Mark Dyson, The Role of Renewable and Distributed Energy in a Resilient and Cost-Effective Energy Future, Rocky Mountain Institute,
December 2017, https://d231jw5ce53gcq.cloudfront.net/wp-content/uploads/2017/12/Insight_Brief_Puerto_Rico_Resilient_CostEffective_Energy.pdf.
63
“Power Restoration Project,” Presentation, Federal Emergency Management Agency, December 2017.
64
Noel Zamot, “Puerto Rico’s Future Energy Utility,” Presentation, Federal Oversight and Management Board for Puerto Rico, December 2017.
65
Governor of Puerto Rico, “PREPA's Governing Board Adopts a New Vision for the Transformation Announced by the Governor of Puerto Rico,” Press
release, Puerto Rico Electric Power Authority, February 1, 2018.
60

49

 Comparison and Characterization of PR Recovery Plans as of April 30 2018
DOE 59

DERs

T&D

Transmission
Infrastructure

Distribution
Infrastructure

Distributed
generation from
renewable resources,
diesel generators,
energy storage
technologies, and
demand response

NYPA 60

CRS 61

RMI 62

Existing wind and
solar integration
DERs for resiliency goals, require grid
(microgrids); DERs
modernization.
for cost savings
Potential
(energy efficiency, interconnection with
demand response)
USVI/other
Caribbean for
balancing

FEMA 63

PREPA 65

Generation closer Customers empowered
to demand; Grid to to allow behind-theUtilized for
serve as an energy
meter distributed
hardening
platform that
generation; grid
operations,
allows entry of
designed to take
improving
innovative
advantage of
resiliency
technology and
distributed energy
solutions
resources

"Build Back
Better": modernize
via smart grid
investments,
including increased
automation
Harden T&D
infrastructure for
greater storm
Repair where
resiliency,
needed, replace to
including relocation
hardened
of substations and
specifications at
upgrading relay
minimum, consider
protection
to enable
and pursue grid
DER/microgrid
modernization
integration
alternatives where
possible
Relocate lines and
upgrade for more
automation

PROMESA 64

Scalable grid
architecture
(future proofing)

Harden and
modernize where
feasible

Relocate/construct
new lines; elevate
substations

Update grid ties

Harden
generation
assets;

New Energy Grid
Infrastructure
(Smart Grid, Micro
Grids, etc.)

Reduce
distribution
line lengths

50

 Comparison and Characterization of PR Recovery Plans as of April 30 2018
DOE 59

Communications
& Controls

System Design

System
Operations

NYPA 60

CRS 61

RMI 62

FEMA 63

PROMESA 64

Deploy novel
“sensor-enabled”
Upgrade to modern
monitoring and
Integrate smart
control systems
control systems;
sensors and control
(ADMS, DERMS,
identify and mitigate
technology to locate
two-way
cybersecurity risks
problems rapidly
communications)
inherent to advanced
ICT

Advanced control
systems
(demand matching,
etc.)

Strategic use of local
DERs, managed
Opportunity to
through microgrids Incorporate hazard
move generation
or other
resilience, including Incorporate energy assets closer to
interconnection
RE and DER
storage to help with
load (e.g.,
arrangements, to
including energy
RE demand
diesel/solar,
help reduce the
storage and
balancing,
PV/storage) and
severity of power
microgrids to
improving resilience
improve
outage impacts and improve resilience
reliability and
enhance community
resilience
resilience

Generation closer
to demand,
including in the
north; regional /
municipal
minigrids,
including
interconnected
municipal
mini-grids to allow
wheeling between
municipalities; an
energy platform
that allows entry of
innovative
technology and
solutions

Modernize control
center facilities
(hardware and
software), add
mobile backup
control center

Practice stormreadiness (planning,
training, fuel level
maintenance)

Remote system
deployment
faster than
transmission
line extensions

PREPA 65

Architecture
(distributed vs
regionalized vs
centralized) is
intentionally made to
balance
reliability/resilience
and cost objectives

Operational excellence
and sound long-term
planning reduce cost to
serve.

51

 Comparison and Characterization of PR Recovery Plans as of April 30 2018
DOE 59

NYPA 60

CRS 61

RMI 62

Governance

Federalization, new
management and
financial structures,
and a new
independent grid
operator

Consider alternative
governance such as
municipals, co-ops,
public private
partnership, or
federalization

Market Structure

Defined consumer
interactions and
inputs, including
transparent rates
structures and the
requirement that
municipalities pay
for electricity

Update load
growth forecasts
and accounting
Dependent on
for services
governance structure
provided by
DERs for new
capital
investments

End-Use
Efficiency

Right-size the capital
investment needed
for grid
modernization by
Rebuilt buildings
updating and
meet or exceed
enforcing building code (IECC 2009)
energy codes and
or above
implementing other
energy efficiency
programs

Promote energy
efficiency to
consumers

Strengthen the
role of the
independent
regulator

RE and EE
lower local air
pollution and
reduce carbon
dioxide
emissions

FEMA 63

PROMESA 64

PREPA 65

Transparent,
accountable and
enforceable
regulation via
independent
regulatory
agency

5 key pillars: customercentric; financial
viability; reliable and
resilient; model of
sustainability;
economic growth
engine for Puerto Rico

Privatization
(From projects to
IPPs to IOUs) to
drive significant
private investment

Privatization

Provide consumer
choice for behind-themeter efficiency

52

 Comparison and Characterization of PR Recovery Plans as of April 30 2018
DOE 59

Environment

Timeline

NYPA 60

Environmental law
requirements limit
cost-effectiveness of
existing fossil-fuel
generation assets,
reinforcing
attractiveness of
renewable
generation and
DERs

10 years

9 years

CRS 61

RMI 62

Climate change
requiring more
robust hardening
efforts for future
preparedness

RE and EE
lower local air
pollution and
reduce carbon
dioxide
emissions,
potential
opportunity for
cost-avoidance
compared to
existing
operating
existing assets

10 years

Near and long
term

FEMA 63

PROMESA 64

PREPA 65

Diversify energy
resources and reduce
carbon intensity of
power sector (primary
and backup generation)

Immediate

Short-, medium-, and
long-term

53

 Appendix C: DOE Recommended Actions
These recommendations are provided for the purpose of informing the Governor’s recovery plan. The Governor
should identify the appropriate actor or agency responsible for implementation. DOE will continue to consult with
relevant Federal agencies and Commonwealth stakeholders on implementing these recommendations as
appropriate.

Transmission and Distribution
1. Investments in grid improvements should be based on detailed modeling, such as load flow
modeling and contingency analysis, to identify the optimal resiliency and hardening benefits
for the transmission system. Re-routing transmission infrastructure does not now, in the
absence of analysis demonstrating its merit, present sufficient benefit to justify the cost. Load
flow and contingency analysis will reveal which lines should be re-routed to increase both
day-to-day reliability and resilience in the case of an event. This modeling will help rightsize and prioritize grid investments, which could otherwise have the potential to put
significant upward pressure on rates.
2. Recovery plans should provide for enhanced and enforced operations and maintenance to
mitigate the disruption caused by the next event. For example, guy wire anchors of
transmission infrastructure and static wire continuity need to be maintained to harden and
add resiliency. Other materials, such as stainless steel or composite anchors, may be needed
to replace some components at existing installations.
3. There are no recommended modifications to the current voltages associated with the
Transmission and Distribution (T&D) infrastructure as they are suitable for the current and
projected electrical needs of the island. However, a long term strategy to maintain
standardization with typical mainland voltage will help future mutual aid response.
4. USDA Rural Utilities Service (RUS) standards should be adopted where feasible and
appropriate to standardize equipment and design, which will aid with replacement in both
regular and emergency situations. USDA RUS standards govern the engineering and
component specification of all voltage ranges of electrical transmission and distribution
networks used by every rural electric utility in North America that borrows from RUS.
PREPA was an active RUS borrower until 2010, so restoring the power grid to meet
applicable RUS standards should be an attainable objective to prepare the utility for near
term emergencies and long term investments. Thus, as part of the reconstruction phase,
Puerto Rico’s grid should be restored, at a minimum, to RUS standards as well as other
applicable standards (e.g., NESC, NEC, NERC-CIP, NIST cybersecurity framework).
5. All replaced poles and towers should be of a design and material to survive 150 mph
sustained winds. If funds are available, electricity transmission towers installed specifically
for temporary emergency restoration after Hurricanes Irma and Maria should be considered
for replacement as soon as practicable, potentially by monopoles. Many round monopole
structures rode through the storm effectively.
6. The PREC should coordinate a joint study with the Puerto Rico Telecommunications Board
to determine and enforce safe loading requirements of distribution poles carrying both
electric and telecommunications infrastructure. Federal agencies can participate as necessary
and appropriate.
54

 7. Implement industry best practices in a comprehensive vegetation management program to
protect the integrity of grid assets.
8. Substation assets should be hardened, including transformers, circuit breakers, associated
switchgear, and especially control equipment, including protective relays and
communications gear. Revised Flood Insurance Rate Maps (FIRM) should be used to site
substation assets to avoid Base Flood Elevation (BFE) + 3.0 feet or 0.2% flood elevation,
whichever is higher. In addition, siting should be outside of the floodplain whenever
possible and existing critical stations should be raised and/or waterproofed accordingly.
Besides relocation, detailed power system simulation will provide insights on which assets to
harden and in what priority.
9. Based on modeling results, strategic, judicious undergrounding of distribution lines should be
considered in limited appropriate circumstances. Based on experiences in Hurricanes Katrina
and Sandy, undergrounding of lines in coastal areas could present risk of salt-water intrusion;
other considerations are the depth of the island’s water table and subsurface rock. Any
underground distribution lines in a floodplain should conform to 10 CFR Part 1022.
10. For the benefit of both day-to-day and in-event scenarios, recovery plans should include a
strong modern Energy Management System, Remote Terminal Units, and other equipment
providing real-time information and control capability to utility operators. For example, AMI
for metering to serve as an operational tool providing real-time information that can, if
implemented appropriately, improve service to industrial customers and reduce non-technical
losses (caused by actions external to the power system such as theft) by enabling targeted
inspections of anomalous readings. Also, this intelligence could empower a predictive
maintenance program.
11. Analysis of the existing communication infrastructure available to support grid monitoring
and control functionality should be performed. This analysis would include: inventory and
document the existing fiber optic cable plant; research ownership of existing cables;
determine fiber connections and fiber terminations availability for secure utility applications;
analyze availability and functional performance and cybersecurity of the existing
communication termination equipment at the substations; identify suitable solutions to
support "last mile" communications to enable system monitoring and control functions,
sensors and other equipment; distribution automation, support; AMI data backhaul; and other
applications and functions.
12. Analysis should be conducted to determine the value of deliberate sectionalizing of the grid.
Generation
13. Evaluate the siting of key generation facilities so that, to the extent practicable, they are colocated with key load centers to reduce the criticality of the transmission system when
recovering from anticipated extreme events in the future. In particular, analysis on repowering Palo Seco with alternative fossil fuels is recommended.
14. Ensure the generation mix complies with all relevant legal and regulatory requirements, both
local and Federal. Preliminary analysis shows that moving toward a more diverse fuel
portfolio, including alternative fossil fuels, renewable energy and energy efficiency, will
produce significant cost reductions. Fuel-efficient load-following combustion turbines could
greatly improve fuel efficiency as compared to conventional steam turbine power plants.
However, as with grid infrastructure, detailed modeling, such as production cost, capacity

55

 expansion analysis and detailed machine modeling, can help determine the best course of
action to integrating new generation sources for Puerto Rico.
15. Given PREPA’s pre-storm estimated sales in 2026, as few as three of PREPA’s current
power plants may satisfy estimated load in ten years, when combined with purchased power.
Any hardening efforts should focus on those plants, including the Costa Sur power plant. As
other facilities are retrofitted, especially Palo Seco, to comply with Mercury and Air Toxic
Standards (MATS) and other relevant legal requirements, detailed hardening assessments
should be undertaken.
16. Evaluate the extent to which integrating small and flexible generation assets near load centers
into a more intelligent system could reduce the number of critical failure points.
17. While much of PREPA’s generation that was operational before the storm was not
significantly compromised by Hurricanes Irma or Maria, a program of hardening generation
assets would ensure continued resilience to weather events, beginning with critical central
plants regardless of ownership. The current excess of generation affords the opportunity to
model energy interdependencies and assess fuel contingencies, including shipping concerns,
source of fuels, storage locations, and the impact of disruption and emergency response.
Analysis can indicate where to prioritize dual fuel generation capability and sufficient levels
of on-site fuel storage.
Microgrids
18. Recovery plans should include analysis to determine the potential applicability and optimal
locations for microgrids, including their specialized role in the system (e.g., serving critical
infrastructure in urban areas, serving unique needs of industrial customers, or serving remote
communities). This analysis should include the availability of generation resources, fuels,
load type, and the boundaries of microgrids.
19. Microgrid designs should rely on a suite of existing tools (e.g., DER-CAM, and the
Microgrid Design Tool – see Appendix D) to help design and value microgrids, once their
location(s) has been identified.
20. Communities that have required generator assets for extended periods of time should
consider microgrids and the potential to leverage temporary generation that has been in
service over the past few months.
21. Analysis as part of the recovery plan should consider and evaluate different pathways to
contain grid failures during future events, and the different roles of transmission
sectionalization and microgrids in providing reliability and resilience.
22. Interdependencies between electric power and other key sectors, specifically water, waste
water, waste, telecommunications, transportation, and public health and safety, should be
assessed and considered when infrastructure funding decisions are made. Potential alignment
and sequencing of federal funding across different agency programs that support various
sector infrastructures, possibly across multiple areas of the islands would be beneficial. The
analysis identified in this report will support that goal.
23. Microgrids may prove effective at ensuring the availability of critical services during an
event. Analysis can help prioritize critical infrastructure for hardening, for example, through
a critical infrastructure resiliency bank.

56

 System Operations, Management, and Planning
24. Training and capacity building, particularly on asset management, system planning, and data
collection should be supported as a part of all infrastructure expenditures, including
Integrated Resource Planning, Energy Assurance Planning, and cost of service accounting.
25. PREPA, PREC, and other Commonwealth agencies and instrumentalities should be
resourced to draft and execute staff training plans as part of expenditures on infrastructure.
To the extent necessary, PREPA should identify skills gaps within its technical and
engineering staffs, and identify whether other groups (such as Administrative and General)
are right-sized to forecasted sales and engineering needs.
26. The recovery plan should call on the utility to identify a core team responsible for IRP
submissions and other regulatory affairs, set aside sufficient resources for their work and data
collection, and utilize additional training from relevant national organizations.
27. The Puerto Rican State Office of Energy Policy or its successor should immediately draft an
updated Energy Assurance Plan, which should be reviewed on an annual basis.
28. Ensure that any and all funded projects are consistent with approved and vetted long-term
plans that provide reasonable assurances of compliance with all local and federal laws and
regulations.
29. The Governor and PREPA should update mutual aid agreements to facilitate the rapid
sharing of emergency aid and resources and ensure that Incident Command Systems are
primed to quickly provide support during the next event.
30. Consider additional legislation and regulation that may improve reliability and resiliency
including, without limitation: regulations that prescribe design and installation standards for
all T&D towers and poles to withstand 150 mph wind speed, regardless of material; all
critical electricity system assets should be located at BFE + 3 feet or the 0.2% flood
elevation, whichever is higher, or sited outside the flood plain entirely, if possible (see note
in Section C1 of this report); and an annual review of the Energy Assurance Plan, and all
associated components, including mutual assistance agreements, and technical and logistical
procedures for Incident Management Teams. To the extent feasible in order to enhance
operational efficiencies and interoperability, regulatory agencies should consider and adopt
relevant NERC reliability standards to be implemented by the Commonwealth.

57

 Appendix D: Microgrid Tools

Distributed Energy Resources - Customer Adoption Model (DER-CAM)
The Distributed Energy Resources Customer Adoption Model (DER-CAM) is a
comprehensive decision support tool for microgrid projects. It is the most widely used model
in the U.S. for determining the optimal distributed energy resource (DER) investments in the
context of either buildings or multi-energy microgrids.
DER-CAM answers several important questions for decisions related to microgrids:
 What is the optimal portfolio of DER that meet the specific needs of this microgrid?
 What is the ideal installed capacity of these technologies to minimize costs?
 How should the installed capacity be operated so as to minimize the total customer
energy bill?
 Where in the microgrid should distributed energy resources be installed and how should
they be operated to ensure voltage stability?
 What is the optimal DER solution that minimizes costs while ensuring resiliency targets?
 1,572 verifiable registered users.
 2,992 projects created by users, and 9,272 recorded sessions accessing the website.
 10,899 job requests communicated direct to the "middleman" server.
 Based on these assumptions, a fair estimate would be that the outside world has tried to
run DER-CAM about 15,000 times.
Example Applications:
• Develop feasibility studies for the majority of the 83 studies for the New York Prize
Microgrid Program (the largest in the United States)
• Optimize the Stone Edge Farm Microgrid (SEM). The SEM is a mile-long power line that
connects a network of electrical services and integrates various forms of distributed energy
generation and storage with real time monitoring and control.
• The DOD Environmental Security Technology Certification Program (ESTCP) which
involves a microgrid at Ft. Hunter Liggett.

58

 Microgrid Design Toolkit (MDT)
Microgrid Design Toolkit (MDT) is a decision support software toolkit that aids designers in
creating optimal microgrids.
Employing powerful algorithms and simulation capabilities, MDT searches the trade space of
alternative microgrid designs based on user-defined objectives (e.g., cost, performance, and
reliability) and produces a set of efficient microgrid solutions. MDT allows designers to
investigate the simultaneous impacts of several design decisions and gain a quantitative
understanding of the relationships between design objectives and trade-offs associated with
alternative technological design decisions. MDT can account for grid-connected and islanded
performance, power and component reliability in islanded mode, and dozens of parameters as
part of the trade space search, and presents designers with an entire trade space of
information from which to base final design decisions.
Without MDT, designers rely on engineering judgment and perhaps a quantitative analysis of
relatively few candidate designs. MDT allows designers to explore a larger field of options
and provides defensible, quantitative evidence for design decisions.
Technological Benefits:
 Provides ability to perform topology optimization
 Illuminates large trade space of design alternatives
 Provides a variety of performance, reliability, and cost-related insights for candidate
microgrid designs
 Provides microgrid designers a full understanding of trade-offs associated with certain
design decisions
 Provides many result views and graphs to help interpret results
Example Applications:
•The Smart Power Infrastructure Demonstration for Energy Reliability and Security
(SPIDERS) program
•The City of Hoboken, NJ backup power system
•The U.S. Marine Corps for Expeditionary Units & Brigades

59