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Smart water management for water safety, accessibility and ... · Data integration, analytics and...
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Smart water management for water safety, accessibility and affordability
27 August | 14:00 – 15:30 | M3
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XYLEM PROPRIETARY / CONFIDENTIAL2
Panelist:
Sarantuyaa Zandaryaa
Programme Specialist
Division of Water Sciences
International Hydrological
Programme
UNESCO
SMART WATER MANAGEMENT F O R W A T E R S A F E T Y ,
A C C E S S I B I L I T Y A N D
A F F O R D A B I L I T Y
J A Y I Y E N G A R
Chief Innovation + Technology Officer
X Y L E M
4
GLOBAL WATER CHALLENGES ARE ESCALATING
5B I L L I O N
NUMBER OF
PEOPLE
PREDICTED
TO FACE WATER
SHORTAGES
BY 2050
126BILLIONLITERS
OF WATER IS
LOST BEFORE
IT REACHES
ITS INTENDED
DESTINATION
80%
OF THE WORLD’S
WASTEWATER
IS DUMPED –
LARGELY
UNTREATED –
BACK INTO THE
ENVIRONMENT
DAMAGE
CAUSED
GLOBALLY
BY NATURAL
DISASTERS
IN 2018
$160BILLION
T E C H NOLO GY, DATA
A N D I N G E NUI T Y
A R E R E S H A PING
T H E F U T URE O F WAT E R
DIGITAL
TRANSFORMATION
INTELLIGENT EQUIPMENT
SMART NETWORKS
ADVANCED DATA ANALYTICS
7
Digital solutionsLeverage power of data
to create a new information
for making better system-level choices and recommendations
DIGITALIZATION IS A KEY ENABLER FOR
ADDRESSING WATERSHED CHALLENGES HOLISTICALLY
• Integration of external data such
as weather and GIS (Geographic
Information Systems) is necessary
• Greater temporal, spatial, and parametric data density
• Increasing interoperability of applications
• Shift from situational awareness to decision support
DRINKING WATER
DISTRIBUTION
WATERSHED
MANAGEMENT
OUTDOOR
WATER
WASTEWATER
TREATMENT WASTEWATER
COLLECTION
DRINKING WATER
TREATMENT
POWERFUL ACTIONABLE DATA INSIGHTS WITH BIG DATA
CLOUD ALARM
DEVICE ALARM
RULE ENGINE
WORK FLOW
MACHINE
LEARNING
ARTIFICIAL
INTEL
Wastewater – Combined Sewer Overflow
S O U T H B E N D , I N D I A N A
C H A L L E N G E
Reduce
combined sewer
overflows into
the St. Joe River
S O L U T I O N
Digital water platform combines
real-time sensor and weather data
and AI to control sewer operation.
R E S U LT S
Overflow volume down 70%
or 1 billion gallons a year.
City saved $500 million.
10
1. Set the ambition at the
CEO and Board level
2. Build an innovation
culture
3. Collaborate with utility
peers
Shared Best Practices:
THE WATER SECTOR MUST WORK TOGETHER
11
Customers
Gov't
Suppliers
Venture
Capital
Universities
NGOs
Direct
Investment
in Start-Ups
Innovation
Ecosystem
Youth
Let’s Solve Water
Thoughts on digital water
KALA VAIRAVAMOORTHY, CEO, IWA
Water sector needs to get Smarter
Digital is really an enabler
Digital Disrupters – data is king
COGNIZANT 20-20 INSIGHTS Siloes, Hare-Horse
Structured Data• Pressures & flows
• Water quality
• Stress & strains
• Age, material…
Unstructured Data• Service history notes
• Customer complaints
• CCTV images
Predictive maintenance
watching assets age in real-time
Internal
Data
External Data• Weather related
• Traffic loading
• Soil condition
• ……………….
Data Analytics
Pipe Replacement
Rehabilitation
Optimal Plan
Pipe Condition
AssessmentURGENT ACTION
MONITORING REQUIRED
REHABILIATION PROGRAMMES
NO ACTION
feedback
Digital ecosystem - connected assets
smart pumps, valves etc.
integration of data &
sophisticated analysis
30 billionRFID tags embedded into our global ecosystem
3.6 billion camera phones in use
250 millionsmart meters in Europe by the end of 2020
real-time data from online sensors
© Sensus
Digital ecosystem - connected assets
smart pumps, valves etc.
integration of data &
sophisticated analysis
real-time data from online sensors
© Sensus
Sources &
Environment
Collection,
Treatment &
DistributionEnd Customers
Process Optimization
sensors + algorithms optimize
treatment, RRR (reduce capex &
opex)
Predictive Maintenance
connected assets reduce downtime
& failures of components &
systems
Customer Engagement
transform customer interaction
model across web, mobile,
connected home…
New products & services
enhance value proposition to
include new water related services
Watershed integrity
proactive remote sensing to
enhance WQ and EQ and improve
sustainability
Can benefit the entire value chain
Sources &
Environment
Collection,
Treatment &
DistributionEnd Customers
Integrated Water Cycle Perspective
Data integration, analytics and visualization allow utility to
manage an integrated system in a holistic and intelligent
way
Can benefit the entire value chain
DifferentiatingSystematicBasic Opportunistic Transformational
Immature
Sophisticated
Mature
Where are you on the Digital Maturity Curve?
DifferentiatingSystematicBasic Opportunistic Transformational
Immature
Sophisticated
Adjust based on past eventsMaintenance upon failure
Sensor Reading
Static Rules
Reactive Intervention
Data on single components
Rule Based Decision
Reactive Infrastructure Mgt. Siloed Operations
• Lack of integration of data
• Lack of integration of systems
Reactive Customer
Engagement
• Supply disruptions• Moving home• Complaints on service
Where are you on the Digital Maturity Curve?
Siloes, Hare-Horse
DifferentiatingSystematic
Sensor Readings
Adv. Data Analytics
Proactive Intervention
Structured & unstructured data from across utility
Dynamic Rules (self-learning)
Predicts before failure happens
External Data Sources
Feedback Loop
Proactive Infrastructure Mgt.
Proactive & Customer Centric
• Improved channels of communication• Advising on water mgt. • Providing saving opportunities• Preparing customers for outage• Retail-type customer engagement
Basic Opportunistic Transformational
Immature
Sophisticated
Mature
Integrated & Connected System
• Connected Assets
• Connected Customers
• Connected Workforce
Where are you on the Digital Maturity Curve?
It’s all about connectedness
Connected CustomerHome Display Unit, Web + Apps, Social Media,
Gamification; Dynamic Pricing
Connected WorkforceIntegrated picture of utility, smart wear, AR, flight
simulator controls
DifferentiatingSystematicBasic Opportunistic Transformational
Immature
Sophisticated
Mature
New Business Opportunities
• Data & Analytics central to business
strategy
• Full integration across systems (ERP,
CRM….)
• New business opportunities (DaaS, Aaas)
• Customer data & organizational flexibility
source drive new business opportunities
Where are you on the Digital Maturity Curve?
Smart ‘health tracking’ toilets - continuous monitoring of
personal health data.
• Data on stool + urine (consistency, colour, freq.)
• Capture data on blood pressure, body fat, wgt.
• Allows consumer to take better control of their own
health and well-being, including their diet
• 9/10 willing to share health data with doctor
Attractive model as both B2B & B2C
Monetizing your data - external
IWA Digital Water Programme
Chart’s the Transformation Journey
1. Set ambition at the CEO and Board level
2. Build a holistic digital roadmap
3. Build an innovation culture
4. Leverage pilots for an agile mindset
5. Develop architecture for optimizing data use
6. Cultivate your digital ecosystem
7. Embrace the digital water value case
8. Unite with water sector leaders to solve key barriers
Insights from 40 utilities shape 8 overarching actions
accelerating the digital water journey
• Digital water is an enabler – helps sector transition
towards a more smarter approach to water mgt.
• Wisdom from data is the key:
• Water sector is data rich but information poor.
• Real value of data comes from bringing it all together - integrate entire utility footprint
to maximize returns
• Move from assumption-based management to more data-driven management
Take home messages
Key Framework for the Digitalization
of Water Management
International Centre forWater Security & Sustainable Management
Bitna Lee Programme Specialist
|| 2019 World Water Week in Stockholm | Smart Water Management for Water Safety, Accessibility and Affordability
Sustainable Development Goals: achieve a better and more sustainable future for all
Paradigm shifts of water issues
Smart Water
Management
Importance of the SWM Assessment
➢Analyze the performance of the
SWM in social, technological,
economic, environmental, and
policy aspects
➢Evaluate the level of Sustainable
Development Goals (SDGs)
implementation
➢ Identify the impact of SWM’s
implementation
Case Study | Paju Smart Water City
“SWC” stands for a city implementing a smart water system for supplyingtrustworthy drinking water to consumers and it manages
water quantity & quality systematically from source to tap by using ICT
Smart Water City
▪ ICT was adapted to enhance management of water from the source to the tap
Paju Smart Water City
▪ Location : the western center of Korea-peninsula▪ Population / Area : 420,532 / 672.47㎢▪ Water source : 2 (Han River, Im-jin River)▪ Water supply rate / Revenue rate : 96% / 86.3%▪ Pipeline length / Reservoir : 2,072km / 33EA▪ Regional characteristic
- the mixed type of new town and rural area
MDL
Han River
Im-jin RiverSection B
Section A
Smart Devices Smart Solutions Smart Services
• Normalization of
Chlorination
• Pipeline diagnosis device
• Water quality sensors
• Smart meters
• Water-NET monitoring
system
• Remote leakage monitoring
system
• Real-time water quality
information system
• Reflecting consumer’s
needs
❖In order to provide healthy tap water, ICT is adapted through all water supply processes
Paju Smart Water City
Outcome | Smart Water City (SWC)
1%
35%
36%
55%
37.3%
92.3%
1.3cases
4.5cases
❖Paju citizens are being supplied with healthy water
Tier 1
DesignedSTEEP-based
Analysis Framework
Tier 2
DevelopedSWM
Comprehensive Performance
Indicator System
Tier 3
Conducted Five Core Expert Groups Review &
Evaluation
Research Processes
ECONOMY
ENVIRONMENTTECHNOLOGY
POLICYSOCIETY
Tier1. Designed STEEP-based Analysis Framework
SWM
Objective Category Indicator
Policy and administrative changes
about Water Management
Policy
Water supply
Water quality
Water use and efficiency
Ecosystem conservation
Stakeholder participation and reflection
Water related disaster reduction
Applied Technology TechnologyWater quality management
Water management infrastructure
Rate of change of ecosystem about Water
ManagementEnvironment
Environment of water quality
Water related ecosystem environment
Water related living environment
Changes(Effects) in economic condition of
the water industryEconomy
Direct economic effect
Indirect economic effect
Changes in social structure and recognition
Society
Realization of water welfare
Citizen participation
Quality of life improvement
Tier2. SWM Comprehensive Performance Indicator System
Tier2. SWM Comprehensive Performance Indicator System
Tier3. Five Core Expert Groups Review & Evaluation
‣ The results of the indicator system and frameworks are reviewed by experts
‣ Each group of experts evaluated the importance, compliance, satisfaction, contribution level of the case of SWM
<Performance Score by SDGs Targets>
The SDGs performance score was 84.6 points, which is derived as"relatively high level" and SDG 6, 7 and 11 were well promoted.
Performance of Paju SWC on SDGs Achievement
Comprehensive Performance of Paju SWC on STEEP
<Comprehensive Performance Levels>
<Performance Level on STEEP fields>
Takeaway messages• The assessment frameworks provided better understanding of the SWM
impact on how the SWM impacted water management on STEEEP fieldsand accomplishment of SDGs.
• Paju Smart Water City contributed to achieving SDGs especially for access to clean drinking water and directly impacted to local residents’ satisfaction.
• To enhance its effectiveness, local government’s active support and sustainable management are necessary.
• SWM impacts to economic, environmental and social aspects of human life. With technological development and governance support, SWM can be the next paradigm that can solve the water challenges that we are facing.
• SWM will bring us closed to the vision of a world in which all persons can benefit from improved water resources management and better access to water supply and sanitation services.
Future prospects
Case study
Methodology
UNESCO Event / Name / other Date
Uptake of SWM systems in a developing world context
World Water Week
Sarantuyaa Zandaryaa and Alexandros K. MakarigakisUNESCO Water Sciences Division / Intergovernmental Hydrological Programme (IHP)
27/08/2019
UNESCO Event / Name / other DateWorld Water Week
IHP evolution: shifting to a holistic and integrated approach
IHP-IX
2021
27/08/2019
IHP SWM Publication
UNESCO Event / Name / other Date
Towards Integrated DSS
Once a confirmed alarm is raised, how to best evaluate the risks and implement
response and mitigation actions?
UNESCO Event / Name / other Date
A QUICK REALITY TOUR
27/08/2019
UNESCO Event / Name / other DateWorld Water Week 27/08/2019
UNESCO Event / Name / other Date
OVER 500 INFORMAL PROVIDERS IN
GREATER MAPUTO
27/08/2019
UNESCO Event / Name / other Date27/08/2019
UNESCO Event / Name / other Date27/08/2019
UNESCO Event / Name / other Date27/08/2019
Axis 1: Mobilizing international cooperation to improve knowledge and innovation to address water security challenges.
Axis 2: Developing institutional and human capacities for water sustainability innovation
Axis 3: Enhancing policy advice to reach water
security at local, national, regional and global
levels.
IHP-VIII: Addressing water security:
local , regional and international challenges (2014-2021)
Educational tools for teaching of water issues in the K-12 curriculum in 6 African countries :
• “Water for Schools” project in Cape Verde : Reinforced water education, provided drinking water in 3 schools
• “IESCEE-Cameroun” : School manual “Leçons d’eau” for Water Education
• “Education on Water for Sustainable Development in the Portuguese Speaking African Countries (PALOP)” Technical meeting in Mozambique (Aug. 2015)
Courses and educational tools in the Arab region :
• General guide for teachers in the Arab Countries and Water Education workshops for teachers with UNESCO Cairo: development of interactive activities related to school students. Regional workshops on “Water Education Training for Teachers” (Egypt, September 2016 and March 2017), and a regional training (Egypt, August 2017) to present the guidelines.
Online survey 2017 on Youth Employment and Unemployment in the Water Sector: helped formulating policy recommendations and dedicated IHP activities: received more than 700 responses.
Continuous involvement of youth in global meetings :
6th Africa Water Week (AWW) : side event “Fostering SDG8: Innovative Job Creation and Young Water Professionals Role” , Youth Forum at the Budapest Water Summit, events at COP22, Regional Youth Parliament for Water for LAC, events at 8th World Water Forum.
Past and Current activitiesEducational Tools & Youth involvement
Water EducationWeb Tools & Open-Source initiatives
IHP-WINS: The IHP Water Information Network System online platform:
open access participatory database to foster knowledge sharing and access to information, including GIS
data on water resources. Freely available to Member States, water stakeholders and partners
HOPE-Initiative : Hydro free and/or Open-source software Platform for Experts initiative. Engaged experts in capacity development and training, based on the use of Free and Open Source Software (FOSS).
FREEWAT : FREE and open source tools for WATer resource management: HORIZON 2020
project. FREEWAT platform : for the simulation of water quantity and quality in surface water and
groundwater with an integrated water management and planning module. Increase efficiency in water
management and enable greater cooperation among water regulators, operators and users.
Coordination and data management of all training activities for IHP and the Water Family
• Water Education is also collecting and gathering
data from IHP and the Water Family concerning all
Training and/or capacitating activities.
• Last year, 15. 320 people were trained through to
579 IHP activities in 96 countries, thanks to our
large pool of experts and a solid network !
Challenges & future developments
What are the remaining Challenges ? • Sustainable development based on innovation requires a critical mass of human
resources
• Capacities for uptake and development of technology and innovation is not given
• Obtain and collect data on capacity building to have a clear picture of the state of water
education at all levels
• Develop and promote bottom-up education strategies related to water issues
• Education both formal and informal requires a multi and transdisciplinary approach
• Stay youth-inclusive with a continuous focus on gender equality
• Engage mass media in awareness raising campaigns and programs
Thank U
4 UR
@10Ti
Project introduction
Examples of Smart Water Management in
Developed and Developing Countries
World Water Week 2019
International Water Resources Association
Callum Clench
Executive Director
www.iwra.org
www.iwra.org/swm
Project introduction
To meet the SDGs we need a ‘revolution’, with radical approaches and technology innovation, to have a chance of success by 2030.
- Overseas Development Institute (ODI), 2015
www.iwra.org/swm
Smart Water Management
What is Smart Water Management (SWM)?
The use of real-time, automated and smart Information and
Communication Technologies (ICT) to provide solutions to water
management challenges.
www.iwra.org/swm
Water challenges and priorities addressed using
SWM technology• Water quality
• Water access
• Efficient irrigation
• Leak detection
• Ecosystem protection
• Groundwater management
• Stormwater management
• Floods and droughts
• Community engagement
• Governance
• Data sharing
www.iwra.org/swm
Project introduction
Objectives of SWM Project
• Identify the benefits of SWM
• Analyse how SWM can assist
with meeting the Sustainable
Development Goals (SDGs)
• Understand the enablers and barriers
for SWM implementation
• Support the continued implementation
of SWM for current water challenges
www.iwra.org/swm
Project introduction
About IWRA’s Smart Water Management Project
• Joint collaborative project between K-water and IWRA
• 10 in-depth case studies selected taking place
across 21 countries
• 8 other projects were highlighted for further study
from 9 countries
• Presenting a range of scales, locations, contexts, challenges and
solutions
www.iwra.org/swm
Smart Water Management Project
Countries where the SWM case studies are located
www.iwra.org/swm
Smart Water Management Project
Main Case Studies
www.iwra.org/swm
www.iwra.org/swm
Small-scale agriculture productivity and efficient
irrigation in Southern Africa –
a two-pronged approach:
• SWM technologies monitor soil moisture and nutrients in
real time and facilitate farmer learning about irrigation water
management to increase yield. (Zimbabwe, Mozambique,
Tanzania)
• Agricultural Innovation Platforms (AIPs), bring key
stakeholders together to develop solutions to turn increased
yield into increased profitability.
346 / SMART WATER MANAGEMENT PROJECT
uploaded when the reader comes into Wi-Fi contact. In this way, the farmer sees the data in
the field when recorded, but at the same time, the process records the entire season’s colour
pattern online. Farmers can access this pattern through their phone, but they also record the
data in their field books.
Colour provides a common language about a plant’s ability to extract moisture from the soil.
Importantly, because the sensors measure soil tension, calibration is not required and the
‘language’ is independent of soil type: however, soil type will influence how quickly the colour
changes from blue to green to red. Information on water availability enables farmers to avoid
water stress, waterlogging and fertilizer leaching and learn about the value of rainfall. Farmers
receive information to make better irrigation decisions and understand the seasonal progres-
sion of crop root depth and moisture needs in the soil profile.
Figure 6. ChameleonTM soil moisture sensors and reader (Photo: VIA Farm website)
Figure 7. Farmer demonstrating the use of the Chameleon r eader at Kiwere scheme
The second device is the FullStop, which enables the measurement of soil nitrate and salt
levels. The funnel-shaped devices are buried at approximately one third and two-thirds of the
expected depth of the crop’s root system (Figure 8). As water moves down the soil profile and
reaches the wetting front detector, it is funnelled into one or both of the devices depending
on three factors: amount of water applied, soil type and initial soil moisture. When suf icient
moisture enters the device the indicator above the surface rises. The indicator is magnetically
latched in the up position to tell the farmer that a soil water sample has been captured. This
water sample is then extracted (using a rubber tube and syringe) and tested for nitrates (using
colour test strips) and salinity (using a modified electrical conductivity meter that also uses
colour through lights). The team is in the process of developing an automated version of the
FullStop that works in a similar manner t o the Chameleon sensor.
C A S E ST U DI ES TRANSF O RM ING SM ALLH O LDER IRRIG ATIO N INT O PRO FIT ABLE AND S ELF- S USTAINING S YSTEM S IN SO UTH ERN AFRICA
www.iwra.org/swm
Small-scale agriculture productivity and efficient
irrigation in Southern Africa – some measured
benefits:
• Many farmers have experienced significant yield and
income increases resulting in increased food security and
prosperity.
• The time saved through reduced irrigation frequency has
been invested in further improving yields and/or diversifying
income streams: by establishing and engaging in small
businesses and other non-farm income earning activities
346 / SMART WATER MANAGEMENT PROJECT
uploaded when the reader comes into Wi-Fi contact. In this way, the farmer sees the data in
the field when recorded, but at the same time, the process records the entire season’s colour
pattern online. Farmers can access this pattern through their phone, but they also record the
data in their field books.
Colour provides a common language about a plant’s ability to extract moisture from the soil.
Importantly, because the sensors measure soil tension, calibration is not required and the
‘language’ is independent of soil type: however, soil type will influence how quickly the colour
changes from blue to green to red. Information on water availability enables farmers to avoid
water stress, waterlogging and fertilizer leaching and learn about the value of rainfall. Farmers
receive information to make better irrigation decisions and understand the seasonal progres-
sion of crop root depth and moisture needs in the soil profile.
Figure 6. ChameleonTM soil moisture sensors and reader (Photo: VIA Farm website)
Figure 7. Farmer demonstrating the use of the Chameleon r eader at Kiwere scheme
The second device is the FullStop, which enables the measurement of soil nitrate and salt
levels. The funnel-shaped devices are buried at approximately one third and two-thirds of the
expected depth of the crop’s root system (Figure 8). As water moves down the soil profile and
reaches the wetting front detector, it is funnelled into one or both of the devices depending
on three factors: amount of water applied, soil type and initial soil moisture. When suf icient
moisture enters the device the indicator above the surface rises. The indicator is magnetically
latched in the up position to tell the farmer that a soil water sample has been captured. This
water sample is then extracted (using a rubber tube and syringe) and tested for nitrates (using
colour test strips) and salinity (using a modified electrical conductivity meter that also uses
colour through lights). The team is in the process of developing an automated version of the
FullStop that works in a similar manner t o the Chameleon sensor.
CA S E ST U D I E S TRANSF ORM ING SM ALLHOLDER IRRIG ATION INT O PROFIT ABLE AND SELF- S U STA INING S YSTEM S IN SOUTHERN AFRICA
www.iwra.org/swm
Small-scale agriculture productivity and efficient irrigation in
Southern Africa –
both prongs are essential:
• The soil monitoring tools are sophisticated but simple-to-use SWM
technologies that support a farmer-centred learning system.
• The AIP draws from systems thinking, it promotes learning process by
bringing together stakeholders with a shared interest, builds capacity and
networks, and facilitates a dialogue to identify critical barriers and
appropriating hard and soft technologies to improve profitability.
Project introduction
SWM Benefits – Social:
www.iwra.org/swm
Project introduction
SWM Benefits – Economic:
www.iwra.org/swm
Project introduction
SWM Benefits – Environmental:
www.iwra.org/swm
Project introduction
Policy Recommendations
SWM for an improved quality of life (Society):
www.iwra.org/swm
Project introduction
Policy Recommendations
Investment in SWM for improved resilience and sustainable
development (Economy):
www.iwra.org/swm
Project introduction
Policy Recommendations
SWM for protecting and conserving water resources and
ecosystems (Environment):
www.iwra.org/swm
Project introduction
Conclusions:
• As SWM is still an emerging field these projects demonstrate the
untapped potential of what can be achieved using innovative SWM
technology and solutions, from integrated smart cities to poor rural
villages.
• As the field progresses and technologies evolve, the potential for SWM
adoption across all contexts will continue to grow, leading to increased
opportunities for both developed and developing regions, and innovative
solutions for our current water challenges.
www.iwra.org/swm
Project introduction
Conclusions:
• Now that a wider number of smart tools are on the market, integrated
smart networks will start to emerge, and with them increasing
opportunities for sustainable cities and regions to integrate their various
smart infrastructure, such as smart energy grids.
• While retrofitting existing cities is possible, the opportunity offered by
urbanization and the creation of new cities and suburbs means that
these new urban environments offer the greatest potential for smart
technology integration.
www.iwra.org/swm
Project introduction
Conclusions:
• SWM solutions are not just for wealthy countries or for urban centres.
They have the potential to have proportionally even greater impacts in
poor rural environments.
• When implementing SWM solutions, never forget the human element.
Social benefits are by far the greatest, but a lack of community support
or capacity building can be barriers to success.
www.iwra.org/swm
www.worldwatercongress.com