Understanding our Water Footprint: De-risking Operations Ed Kirk, Johns Hopkins University Jonathan Lanciani, Sustainable Water.
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Understanding our Water Footprint:De-risking Operations
Ed Kirk, Johns Hopkins University Jonathan Lanciani, Sustainable Water
Water Apocalypse
Risks: Rates, Availability, Infrastructure, Environmental Pressure
Only 5-10% of “drinking” water produced will be used for consumption.http://www.virginiaplaces.org/watersheds/drinkwater.html
History of drought in region
A more sustainable water cycle…Decentralized Reclamation and Reuse
Before
After
Water: The Lynchpin toJHU’s Way of Life
Solutions for a Range of End Users
• Est. 1876• 20 M GSF of Buildings • 21 MW of CHP across 5 systems• 50,000 tons of cooling and steam• 320 M Gallons of water annually
Johns Hopkins University
Mission: Ensure JHU is sustainable and remains strong and vibrant
2009 JHU Task Force on Climate Change
• From the Committee:
Possible to reduce GHG by 141,600 MT CO2e
No one way to reach the goal.
Business as Usual growth rate: 0.3% annually.
Result = 51% reduction in GHG by 2025.
JHU Sustainability Efforts
But what about water?? Water use ROSE 9% in 2010
Since 2008:• Reduced GHG Emissions by 23% while
the campuses have grown by 9%• Sustainable Purchasing initiatives• LEED certification on 12 buildings• Waste diversion increased more than
50%• Already conserving and treating
stormwater
What’s Been Done…
Energy Efficiency and the CHP at JHU
3 Cogeneration Plants (18MW)• Increases Plant EE & Reduces
carbon footprint
Trigeneration Plant (1.5MW)• 85% better than grid electricity
Small CHP (75KW Modules)
Results:• Displace High Carbon content grid
electricity• Capture & use waste heat
National Recognition
Setting Standards for Efficiency and Reliability
Risks to Water
Baltimore: Rates set to rise 11% over next 2 years
Rising Rates
2013 2014 2015 2016$0.00
$2.00
$4.00
$6.00
$8.00
$10.00
$12.00
$14.00
$16.00
Sewer Rate Water Rate Combined
$ /
1,00
0 G
allo
ns
$10.54$11.52
$12.79$14.20
Maryland’s Aging Infrastructure
$13 billion Infrastructure Investment Needs Through 2030
Risk Mitigation
N+1: Reliable and Safe Alternatives to Potable Water
Campus water objectives:• Redundant Water Supply
– Drought– Municipal infrastructure failures
• Additional On-Site Storage• Flexibility & Resilience• Independence• Availability in the event of failure• Minimum recovery time• Insulation from rising water costs
Drought
Rising Rates
Aging Infrastructure
Solution: Reuse WaterA logical extension to conservation efforts
Eliminate Risks, Save Money and Increase Sustainability
Cost Savings• Discounted water rates• Reduced potable water intake• Reduced sewer fees
Environmental & Social• Decreases diversion of water from ecosystems• Decreases wastewater discharge• Net energy efficiency gains• Reclaimed water shows no danger to public health
Operational• De-risks operations with an alternative water source • Protects against mandatory conservation programs
Centralized vs. Decentralized Reuse
Impractical for Baltimore, MD
Water Treatment Facility End User~10+ miles
WastewaterReclaimed Water
The Embodied Energy of Water
Overview
Validating Impact & Developing a Plan
• WW flow projections
• Economic assessment
• Water balance & use
• Non-potable demand
• Infrastructure review
• Regulatory review
Water Footprint Assessment & Economic Validation
Site & Infrastructure Assessment
• Prelim. siting & design
• Lifecycle Savings
• Equipment inventory
• Program admin.
Utility Water Assessment
• Water quality needs
• Reclaimed water modeling
Utility & Sewer Data
Predictable Demand
Janu
ary
Febru
ary
Mar
chApr
ilM
ayJu
ne July
Augus
t
Septe
mbe
r
Octobe
r
Novem
ber
Decem
ber
-
50,000
100,000
150,000
200,000
250,000
300,000
Wyman North Plant Main Plant Total NPD
Gal
lon
s p
er D
ay
Non-potable Process Water Demand
36%Utility
56%Domestic
8%Irrigation
Some Independent Power ProducersCurrently Using Reclaimed Water
Water Reuse is Prevalent Amongst IPPs
AutomaticBleed
Evaporator
Condenser
Joy Aftercoolers
Bleach
Dilution WaterStatic Mixer
CL-40
Joy Air Compressorsand Intercoolers
Joy AirCompressor
2 AmmoniaCondensersOil Coolers
Intercooler toAmmonia Receiver
CL-1468BoosterPump
AutomaticController
MarleySigmaTower
MarleyTowers
Carrier NH3Chiller 400 Tons
Evaporator
Condenser
Carrier NH3Chiller 1,000 Tons
Joy
Joy
Aftercooler
New JoyTurbo Air
Compressor
Chemical Feed
Supply
Return
Utility Assessment
Biological studiesCorrosion studies
AutomationTreatability studiesEquipment Integrity
Utility
CBCB
Storage Tank
Deaerator
2
1
3
BoilerFeedwater
Pumps
V-821DA Heater &Storage Tank Boiler
FeedwaterPumps
SB-821Cleaver-BrooksBoiler (1991)32,000 pph
SB-820Cleaver-BrooksBoiler (1991)36,000 pph
ZeoliteSofteners
#2 Powerhouse
Main Steam Header
Condensate Return
V-822CondensateFlash Drum
Steam Supplyto Emulsion Breaking
CondensateReturn from
Emulsion Breaking
CBSB-821
Cleaver-BrooksBoiler (1991)32,000 pph
CondensatePumps
#1 Powerhouse
3
• Feasibility and treatability studies
• Scale inhibitors • Sludge dispersants• Treatment specifications• Purity studies• Corrosion studies• Fuel conservation studies
Superior Program Oversight: Unparalleled Collaboration
Non-Potable Demand
88,000 GPD
175,000 GPD
508,000 GPD
Water Purchase Agreement
Water is Principal to Facility Operations
Flexible project financing arrangements utilizing:~ Performance Contracts ~ Operating Leases ~ Design-Build Agreements
Benefits• No up-front capital• Innovative Technologies• Leverages superior credit
rating• Immediate, Guaranteed
Savings• Long Term Pricing Stability• No O&M Responsibilities• SW bares majority of risk Yr 1 Yr 5 Yr 10 Yr 15 Yr 20
$-
$2,000,000
$4,000,000
$6,000,000
$8,000,000
$10,000,000
$12,000,000
200K GPD 300K GPD 400K GPD 500K GPD
Cum
ulati
ve S
avin
gs
The WaterHub™
Student Engagement: Functional, but also a Living, Learning Classroom
Water Reuse in Urban Spaces
Decentralization Creates New Dynamics: Safety, Aesthetics & Footprint
VS.
Complex, Adaptive Ecosystems
Increased Biodiversity, Reduced Energy Requirements
Reciprocating Tidal Wetlands
Primary Tank
Paired ReCip Cells Filtration & Disinfection
Reuse Tank
Aeration
Artificial Media
Root Zone
Plants & Supporting
Media
Mechanical Room
Ed Kirk (443) 997-2343ekirk3@jhu.edu
Jonathan Lanciani (804) 965-5590 Jonathan.Lanciani@sustainablewater.com
QUESTIONS?
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