290 likes | 468 Vues
Seville Palace Hotel, México D.F., México, 17th to 19th Sep, 2014. How Science of Today meets City of Tomorrow’s water needs. PROF . AVNER ADIN Hebrew University of Jerusalem Adin Holdings “Water Solutions ” Avner.adin@mail.huji.ac.il. Outline. Introduction: The “City of Tomorrow”
E N D
Seville Palace Hotel, México D.F., México, 17th to 19th Sep, 2014 How Science of Today meets City of Tomorrow’s water needs • PROF. AVNER ADIN • Hebrew University of Jerusalem • Adin Holdings “Water Solutions” • Avner.adin@mail.huji.ac.il
Outline Introduction: The “City of Tomorrow” Objectives and methodology Identifying city water management components Understanding the new water cycle Deriving water quality control challenges Science and technology roles, examples Conclusions
World population growth The world population grows and requires more and more resources - arable land, water, energy, and biological resources About 3.5 billion people across the globe already live in cities; the number is expected to grow up to 6.5 billion people by 2050 Expected to reach a peak of growth. Than declines due to economic, health, land exhaustion and environmental reasons.
Declaration: There is enough water on the surface of the Earth for many generations to come. However, . . . Inadequate water quality prevents using its full potential
Objectives and methodology Objective: to indicate scientific research needs in meeting tomorrow’s city water demands. • The methodology is composed of two major steps: • various water system functions and roles are analyzed and listed in four categories: health, aesthetics, recycling and water-energy components; and • the various functions are incorporated into one water cycle, a holistic analysis is being made, from which scientific research challenges are derived.
The city is the future It is evident that more and more people live in cities Thus optimizing the cities infrastructure prepares the world for coping with future population growth Strategic plan:Focusing on urban water management and urban agriculture, using advanced technologies and a strong knowledge center
AH Concepts for Future City • Future City - A healthy community: • Water filtration and disinfection complying with current and future standards • Water quality monitoring, including innovative real time devices for Water Security and Safety • Treatment and quality control of domestic and non-domestic wastewater • Fire hydrant systems • Future City - A beautiful and fun community: • Effective water management for Gardening and parks • Surface water quality control • Fountains and recreational facilities
AH Concepts for Future City (cont.) • Future City - A water recycling community: • Planning and design of grey water and wastewater collection and reuse systems • All grey water and wastewater shall be reused within the Future City area • Sludge free wastewater treatment where possible • Future City - A water and energy conserving community: • Supply management and leakage control, with continuous data collection (and automatic billing) • Public education ! • Minimizing energy usage in water and wastewater facilities
Urban agriculture Urban agriculture contributes to food security and food safety in two ways: It increases the amount of food available to people living in cities It allows fresh vegetables and fruits and meat products to be made available to urban consumers
Water quality challenges in RWC Corrosion, minerals absense Water security Nature Crypto, virus, algae NPs Microorganics, metals Boron, pharma
(2014)New water production-Israel Operating Starting Planning Shomrat100? MCM Hadera 127 (200) MCM Sorek 150 MCM Palmakhim 90 MCM Ashdod 100 MCM Ashkelon 120 MCM Reuse Desal. • Mixing • water • Qualities • Surface • Ground • Stormwater • Desalinated • Recycled Reversing the flow
Slow sand filtrationMechanisms • Biological: enhanced bio-activity on grains surfaces. “Schmutzdecke”. • Physical: surface straining, interstitial straining, settling, diffusion. • Physicochemical: Adsorption, DLVO-van der Waals interactions. • Surface catalyzed degradation
On-site systems, • decentralized • Electroflocculation-constructed wetland hybrid • Aerobic-anaerobic compact system
PRODUCT TANK SHAFDAN WASTEWATER Principle flow diagram for a 20,000 m3/day IMS system – encased UF UF SYSTEM 11 UNITS x 45 MODULES total filter area – 24,750 m2 RAW WATER PUMPS (P1) HIGH PRESSURE PUMPS (P3) st I. 68 X 7 INTERIM TANK st II. 28 X 7 UF PUMPS (P2) FILTERED WATER TANK RO SYSTEM 2 UNITS x 10,000 m3/day TO DRAIN BACKWASH PUMPS (P7) st I. 68 X 7 st II. 28 X 7 TO DRAIN
Wash step Load step Exchange step NaOH Stabilized water Low TDS brine Back to RO process [Mg2+]>0 75% Cation Exch. resin CaCO3(s) 25% [Mg2+]=0 Seawater or 1st stage brine following UF pretreat. Water from RO process Back to the sea H2SO4 to pH around 2.1 Mg remineralizing novel system
Nanoparticles removal • Itis inevitable that nanotechnology-based consumer products enter the aquatic environment • Switzerland (2014): Engineered nanoparticles are present in the leachates from landfills and are released to surface water • Viewed as emerging pollutants: toxic, may cause cancer, neurodegenerative diseases and other types of diseases • Their eco-environmental risks demonstrate strong need of developing effective water treatment processes
NP removal mechanisms Reaction/ effect Transport Attachment k β α (Wiesner, 2014)
Nanoparticles and biofilm • The fate and transport of NPs are affected by biofilms. • Biofilms consist of bacteria and surrounding EPS (extracellular polymeric substances) • NPs can be transported and strongly attach to EPS surfaces • Initial studies (2009) have shown significant accumulations of NPs occurring in biofilms. • Indication (2014) that NP’s attachment to EPS is governed by electrostatic interactions • Mg presence may enhance biofilm formation
Bio-fouling prevention E.coli inactivation by molecular capped Ag- Nano-particles Avner Adin Hadas Maman Gil Markovich Avital Dror-Ehre
Some of recent Israeli novel technologies • Flexible filter beds with controlled porosity • Fiber optic technology which recycles UV photons • Detecting and counting bacteria in minutes instead of days • Sludge-less bio-reactors • Aerobic membrane bio reactor that consumes no energy for aeration • Hydrophilic membrane with higher flow at lower pressure • Electricity produced by electro genic bio-reactor.
Regulations and standards Wastewater quality for unrestricted irrigation Wastewater quality for disposal to streams Industrial effluent quality Drinking water quality Desalinated water quality Materials and equipment
Conclusions • More than 70% of the world population will live in cities • Future City’s water can be best managed with the help of science under four categories: health, aesthetics, recycling and water-energy • A holistic interpretation of the water cycle can lead to the necessary scientific research challenges • Upgrade of regulations and standards is needed, must be based on scientific knowledge • Cooperation in water research among Mexican and Israeli scientists can lead to improved water management in the years to come
WATER IS LIFE www.adinholdings.com