MARKET RESEARCH REPORT - AWA · AUSTRALIAN WATER ASSOCIATION – MARKET RESEARCH REPORT Part 1:...
Transcript of MARKET RESEARCH REPORT - AWA · AUSTRALIAN WATER ASSOCIATION – MARKET RESEARCH REPORT Part 1:...
MARKET RESEARCH REPORT
WATER SECTOR IN VIETNAM: OVERVIEW, RECENT TRENDS
AND OPPORTUNITIES FOR COOPERATION
PART 1
DRINKING WATER SECTOR IN VIETNAM
Prepared by:
David Nguyen
Daniel Nguyen
Paul Smith
An Nguyen
Vietnam, October 2017
Contents
1. COVERAGE: ASSESSING THE PAST PROGRESS ........................................................................ 1
2. RAW WATER SOURCES ..................................................................................................................... 3
2.1. The quantity ....................................................................................................................................... 3
2.2. The quality ......................................................................................................................................... 7
3. URBAN WATER SUPPLY [2] ............................................................................................................ 12
4. RURAL AND HOUSEHOLD WATER SUPPLY ............................................................................. 16
4.1. Rural water supply ........................................................................................................................... 16
4.2. Household water supply ................................................................................................................... 19
5. INDUSTRIAL WATER SUPPLY ....................................................................................................... 20
6. THE RECENT TRENDS ..................................................................................................................... 23
6.1. The legal framework ........................................................................................................................ 23
6.2. Equitization of the water sector ....................................................................................................... 24
6.3. The technological aspect .................................................................................................................. 24
6.4. The climate change and environment aspect ................................................................................... 28
7. OPPORTUNITIES FOR COOPERATION ....................................................................................... 30
7.1. Public investment ............................................................................................................................. 30
7.2. Private investment ............................................................................................................................ 32
REFERENCES .......................................................................................................................................... 35
ABOUT THE AUTHORS ........................................................................................................................ 37
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1. COVERAGE: ASSESSING THE PAST PROGRESS
Figure 1: Lack of clean water supply in
1900s (Source: http://www.viettoc.org)
Figure 2: Constructing clean water supply
system (Source: http:// vietnamnet.vn)
With a population now in excess of 88 million, Vietnam is the world’s thirteenth
most populous country. It has also experienced one of the world’s highest economic
growth rates over the past two decades and recently graduated from low- to middle-
income country status. This growth has been accompanied by a dramatic decline in the
rate of poverty, which fell from 58% in the early 1990s to 14.5% by 2008. Data from the
Joint Monitoring Programme (JMP) suggest that Vietnam has taken great strides in terms
of increasing access to improved water supply and sanitation. In the case of urban water
supply, the 1990 access rate to improved facilities was already high at 88%, and by 2011
had reached 99%, with 58% having a house connection. Nevertheless, there are
significant disparities in access and service quality between big cities and smaller urban
centers. In rural areas, access to improved water supply rose from 50% in 1990 to 94%
by 2011, though only 9% have house connections. The most common types of improved
source used are boreholes or tube wells, protected wells and rainwater collection—each
accounting for roughly one quarter of improved facilities [1].
Up to the end of 2011, according to MoC, Vietnam has had 753 urban areas that
are classified as follows:
2 special urban areas including Hanoi and Ho Chi Minh City
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3 central cities are categories I - urban areas, including Hai Phong, Da Nang
and Can Tho.
8 provincial cities are categories I – urban areas, including Hue, Da Lat,
Nha Trang, Quy Nhon, Buon Ma Thuot, Thai Nguyen and Nam Dinh.
11 provincial cities are categories II – urban areas, including Bien Hoa, Ha
Long, Vung Tau, Viet Tri, Hai Duong, Thanh Hoa, My Tho, Long Xuyen,
Pleiku, Phan Thiet and Ca Mau.
47 urban areas are categories III that are a town or a provincial city
42 urban areas are categories IV that are towns or township, townlets
640 urban areas are categories V that are townlets
By the end of the year 2010, 18.15 million people could have access to drinking
water, accounting for 69% of the total urban population. Percentage of the population
using drinking water in urban areas is recorded as follows: 70% of urban population in
special urban areas and Categories I - urban areas, 45-55% of urban population in
Categories II and III, 30-35% population of Categories IV - urban areas and 10-15% of
population in Categories V - urban areas. The actual data above mentioned is lower than
that of national target program on urban water supply development [2].
Table 1: Objectives of urban water supply development [1]
Indicator Urban type 2015 2020 2025
Service coverage (%)
Categories III or higher 90
90
100 Categories IV 70
Categories V 50 70
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2. RAW WATER SOURCES
2.1. The quantity
Vietnam has about 835 billion m3 / year water surface, in which 522 billion m3 is
the flow from abroad, accounting for 62.5%, only 313 billion m3/year is generated from
the rainfall in the country, accounting for 37.5% [4]. There are about 2,378 rivers over 10
km of length which have a perennial flow, and 15 basins with an area of more than 2,500
km2 of which 10 river basins are of over 10,000 km2 in area. These account for 80% of
the total area of Vietnam. The Mekong River's total runoff accounts for 59% of the total
national runoff, followed by the Red River with 14.9%. And 7 of 10 largest rivers have
basin sharing with the neighbouring countries [5]. With the river system is quite dense,
natural lakes and artificial large and small reservoirs have made Vietnam water resource
quite rich. Table 2 shows some main river catchment basins in Vietnam.
Table 2: Main river catchment basins in Vietnam [6]
Basin over 10,000 km2 Basin 2,500 - 10,000 km2
Bac Giang and Ky Cung Thach Han
Hong (Red) and Thai Binh Huong
Ma Tra Khuc
Ca Kone
Vu Gia and Thu Bon Gianh
Ba
Srepok
Se San
Dong Nai
Cuc Long
The Mekong Delta river system (Figure 3) comprises a relatively dense network of
river courses and canals, including the natural river systems and canals: The main natural
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river branches and canals in the Mekong delta are formed by the two systems of the Tien
River and Hau River (respectively the lower branches of the Mekong and Bassac rivers).
These rivers flow to the sea in estuaries via nine river mouths as Tieu, Dai, Ba Lai, Ham
Luong, Co Chien , Cung Hau, Dinh An, Ba Thac and Tranh De (river mouths in the
territory of Ba Thac in Soc Trang province have been covered in the 1970’s) and a short
river Vam Nao river linking the Tien and Hau main branches. Vam Co River (including
the Vam Co Dong-Vam Co Tay) runs parallel to the east of the Tien River, Cai Lon-Cai
Be River, My Thanh, Ganh Hao, Ong Doc, Bay Hap rivers flow to the West and East
Sea. The Tien and Hau rivers transfer the largest amounts of water with a total annual
flow of 325.41 billion m3 observed at station Tan Chau (on the Tien river) and 82.43
billion m3 in station Chau Doc (on the Hau river); the flow rate on the Tien River / Hau
River is 80/20. Both the Tien river and Hau river are wide and deep, with the average
width of about 1000-1500 m and an average depth of 10-20 m (and locations where the
depth is over 40 m). Vam Co River system consists of two branches (Vam Co Dong and
Vam Co Tay), that originate in Cambodia, and flow east through the Mekong Delta. The
Cai Lon-Cai Be are tidal rivers, derived from the center of the Ca Mau peninsula and
flow to the sea through the Cai Lon river mouth. The estuary is very wide but not deep.
The system of manmade canals in the Mekong delta was constructed primarily during the
past century, with the primary purpose to develop agriculture and transportation. Until
now, the canal system has developed into a dense network with 3 levels of major,
primary and secondary canals. The primary and secondary canal systems have a high
density, with some 80-10 m / ha, and a total of 30,000-40,000 km of canals in all the
Mekong Delta [7]
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Figure 3: Sai Gon River, Cuu Long Basin (apart of Mekong basin) Source:
(http://www.baotainguyenmoitruong.vn)
The Red River (Figure 4) rises in the mountains of Yunnan Province in the
People's Republic of China (PRC) and flows through Vietnam to the South China Sea,
where it forms an extensive delta. Its total catchment area is 169,000 square kilometers,
of which 51 percent lies in Viet Nam, 48 percent in the PRC, and less than 1 percent in
Lao People's Democratic Republic. The climate is tropical to sub-tropical and is
dominated by the east-Asian monsoon. Seasonal variation of rainfall is significant, with
only about 10 percent of the annual total occurring during the dry season from November
to March. Consequently, the basin discharge is highly variable from a minimum recorded
dry season discharge of 370 cubic meters per second (m3/s), to a maximum of 38000
m3/s. The Basin has a population of about 24 million people, of whom 17 million live in
the Delta, making it one of the most densely populated rural areas in the world. The
cultivated area in the Basin is close to 2 million hectares (ha), of which 650,000 ha is
irrigated and 880,000 ha is covered by drainage systems [8]
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Figure 4: Red River Red River Basin. (Source: http://kinhtedothi.vn)
Reserve of underground water according to other exploring documents
is plentiful, but focusing largely in the Southern delta, and shortages in Northern and
Central regions. Currently, the total amount of groundwater which can be exploited
accounts for 20% of the total groundwater reserves which can be exploited. Many
provinces in the country are mining underground water with quite large flow for daily use
and industrial, agriculture and service production. Typically, these are Hanoi with
750,000 m3/ day, Ho Chi Minh with 1,600,000 m3/day, Tay Nguyen with 500,000
m3/day. Currently, there are over 240 urban water supply plants with a total design
capacity is 3.42 million m3/day in which 92 plants use surface water source with a total
capacity of 1.95 million m3/day and 148 plants use groundwater source with total
capacity of 1.47 million m3/day. Many localities use both surface water and groundwater.
Total capacity of existing plants can ensure water supply with 150 liters of pure water per
day for each of the urban population [4].
As recommended by international organizations on water resource, mined water
limitation allowed in countries should be limited within 30% of the flow. Meanwhile,
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according to the Ministry of Natural Resources and Environment, almost provinces in
Centre and Tây Nguyên have been exploited over 50% of the flow in dry season which
makes that rivers exhausted. Regarding Ninh Thuận province alone, the flow has been
exploited 70-80%. The figure of Irrigation Department (Ministry of Agriculture and
Rural Development) shows that water resources in river basins are severely reduced in
number. Red River water level is increasingly lower (dry seasons of the year 2006 - 2007
water level is down to 1.12 m, the lowest level since having monitoring station on Red
River). The dry season in 2010, drought reached a record during the past 100 years in
Red River Delta and 50 years in the Mekong Delta. Even there are days the water of Red
River only left 0.1 m in Hanoi and 0.4 m in Mekong River in Lao. According to a recent
research results of Center of monitoring and forecasting water resource, Ministry of
Natural Resources and Environment, in ten years, the groundwater in some places in
Hanoi down to 6m and some places in Ho Chi Minh City down to 10m. This situation
will worsen in the next century when the water needed strongly increase [4]
2.2. The quality
Many rivers are choked with contamination and untreated waste from craft
villages and industrial production zones in Vietnam. Most of the monitored rivers are
found to be polluted with substances like N and P, from 4 to nearly 200 fold compared
with water resource of type A in and from 2 to 20 times in comparison with water source
of type B in Vietnamese Standard limit. The monitored data for 4 rivers running the main
urban of Vietnam as Red river (Hanoi), Cam River (Haiphong), Huong River (Hue) and
Saigon River (HCM City) The result in Figure 5 and 6 showed that ammonia-nitrogen
(NH4-N) and biochemical oxygen demand (BOD5) vary was considerably and exceed
national water quality class A standards by several fold. The problems are worst during
the dry season, when the flows in the rivers are reduced [9]
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Figure 5: BOD levels in Vietnamese major rivers [9]
Figure 6: NH4 levels in Vietnamese major rivers [9]
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The Cau, Nhue and Day rivers in the Northern Vietnam are also seriously polluted
(Figure 7). Water in the Cau river contains many dangerous pollutants including
industrial lubricants. Waste products dumped in rivers affect natural levels of bacteria
and nutrients and biochemical reactions occur. BOD and Chemical Oxygen Demand
(COD) levels are two to three times higher than Vietnamese standard limits. At a lower
section of Cau river, the water quality had been infected with a high concentration of
BOD and COD, which are 10 times Vietnamese standard limits. By 2010, it is forecast in
the social-economic development plan put together by the provinces which the Cau river
passes through, that levels of BOD will rise by 1.5 times of what they are now,
phosphorus and nitrogen levels are also expected to increase by a similar amount. Rivers,
which run through Hanoi city, are also containing very high concentration of COD, NO2,
NO3- and SS. The water of Nhue river in Ha Tay province is turning black and noxious
[9]
Rivers in the southern region are in deep trouble and in a high alert situation
(Figure 8). Organic pollution in Saigon, Vam Co Dong rivers is very serious. The COD
level is three time higher than it should be. According to MONRE, there are about 4,000
enterprises discharging wastewater, of which 439 enterprises are the most serious, and are
required reallocated, closed or will have to adopt cleaner technologies and treatment of
their wastewater. In accordance with industrial parks (IPs) and export processing zones
(EPZs) in the Southern Key Economic Zone (SKEZ) discharge over 137,000 m³ of
wastewater containing nearly 93 tons of waste into the Dong Nai, Thi Vai and Saigon
Rivers each day. By 2010, waste in the Dong Nai river will increase by 1.7 times
compared with 2007. Meanwhile, two out of 12 IPs and EPZs in Ho Chi Minh City, three
out of 17 in Dong Nai, two out of 13 in Binh Duong, and none of the IPs and EPZs in Ba
Ria-Vung Tau have wastewater treatment facilities [9]
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Figure 7: Pollution in Cau River. (Source: https://www.baomoi.com)
Figure 8: Pollution in Saigon river (source: http://www.thanhniennews.com)
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The level of ammonia in the groundwater in Hanoi is higher than the National
standard by 2-8 times. All samples taken from the upper aquifer exceed ammonia
standard many times. Scientists estimate that with the current abstraction rate of 700,000
m³/day, there will be a high risk of lowering the water table down to 114 m and the
groundwater pollution would spread over the Hanoi city. A broad survey of arsenic
pollution in the 12 provinces of the Red River Delta, Mekong Delta and Central area was
carried out from November 2003 to April 2004 by IET with UNICEF funding support. A
total of 12,439 water samples were tested with arsenic in 419 communes of 33 districts in
the 12 provinces. Analytical results showed that in some provinces of the Red River
Delta and Mekong Delta, where tube well water had arsenic content exceeding much
higher than the Vietnamese allowed standard (there are 34.92% and 21.07 % of tube
wells found with arsenic higher than 0.01 mg/l and 0.05 mg/l, respectively). Especially
some communes in Ha Nam province, the tube wells water was a high arsenic level like
Vinh Tru, Binh Luc, Duy Tien, Kim Bang communes (there are 52.46 % and 35.16 % of
tube wells found with arsenic higher than 0.01 mg/l and 0.05 mg/l, respectively). 3
provinces in Mekong, in spite of that the number of field test was still limited, a
remarkable number of water samples was found with high arsenic in Dong Thap province
(39.15% tube wells found with arsenic higher than 0.05 mg/l) [9]
In Ho Chi Minh city, the Union for Geology No. 8 reported that the number of
damaged wells which could not be used due to salt intrusion was 2,359: equivalent to
2.48 % of all surveyed wells. Among the 11 monitoring wells, which were set-up under
the DOSTE/UNDP project – VIE 96/023 during the first half of 2001, six of them have
recorded nitrogen and pathogen related contamination (nitrate, ammonium and coliform).
In comparison to standards in TCVN 5944 – 1995 (Groundwater quality standard), the
number of wells which exceeded standards for chlorine and pathogenic pollutants was 2
of 11 wells. Iron concentration of groundwater in HCMC is higher than that of the
drinking water quality standards (0.3 mg/l). pH level of most surveyed wells is also lower
than that of the Standards (pH < 6.5). The iron concentration in the lower Pliocene
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aquifer is higher than that of the other aquifers, especially in Cu Chi, Binh Chanh
District. Heavy metals (Cu, Pb, Zn, Hg, Cd, Se, Ni and As) are not detected in all
aquifers. Although Phenol and Cyanogen concentration still meet groundwater quality
standards, they tends to increase with time and should be continuously monitored (Nga
,2006). The coliform contamination happened at some monitoring wells in the
Pleistocene aquifer in 2002 [10]
In 2003, among ten samples, coliform level of three samples exceeded the limited
value of TCVN 5944-1995. In 2004, among ten samples, the coliform number of six
samples was above the limited value. DONRE (2005) reported that Pleistocene and upper
Pliocene aquifers were contaminated by coliform due to infiltration of domestic
wastewater through wells with poor construction and maintenance. TOC level of
monitoring well ranges from 2.8 mg/l to 81 mg/l in 2004. In general, the average TOC
concentration of GW is less than 2 mg/l under an uncontaminated environment (Deborah
Chapman, 1995). Therefore, the groundwater in HCMC could be contaminated by
organic compounds. The high TOC concentration is found in the following areas (i) Dong
Thanh landfill (80.9 mg/l), (ii) Dong Hung Thuan-District 12 (18.1 mg/l), (iii) Bau Cat-
Tan Binh (16.7 mg/l), Tan Tao-Binh Tan (13 mg/l) and (iv) Binh Hung-Binh Chanh (12.5
mg/l). TOC values at these locations in 2004 were higher than that of the previous years,
while TOC at the other locations were stable [10]
3. URBAN WATER SUPPLY [2]
According to Ministry of Construction, current situation of urban water supply in
the whole country is as follows: In Vietnam, there are 68 water supply companies,
supplying drinking water to urban areas with a combined installed capacity of 5.5
million cubic meters per day but operating at 4.8 million cubic meters per day [11].
Surface water sources account for 70% of the total source water and 30% of the rest is
ground water. There are more than 420 water supply systems with a total designed
capacity of 5.9 million m3/day. Operation capacity reaches 4.5 million m3/day, equal to
77% of the designed capacity. Capacity of the water supply system is still limited due to
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inadequate investment in water treatment plants, pipe networks for transmission and
distribution of drinking water supply. According to VWSA, because distribution
networks are not upgraded in synchronization with treatment plants, the rate of non-
revenue water due to water leakage is 30%, especially even up to 38-40% in some cities
such as Hanoi, HCM City. Although current capacity of urban water supply has increased
to 3 times and 2 times in comparison to that of 1975 and 1990, rapid urbanization process
and many industrial parks, newly formed urban areas and sharply increased urban
population, water supply system has not been able to meet all demands of water use from
urban residents. Therefore, two third of small towns are without centralized water supply
systems. Besides, due to difficulties in investment fund and capacity of water supply
companies, the lack of synchronization in planning development of water supply systems
and implementation of the plan, many water supply systems have been upgraded and
their capacities were increased; however, their operation is still under their designed
capacity.
According to Benchmarking data from VWSA only 35 out of 67 cities surveyed
(accounting for 60%) could ensure continuous water supply with 24 hrs/day. In most of
the rest cities, their water supply systems were only in operation in 14-20 hrs/day and for
3-4 cities, the operation was only in 8-10 hrs/day. Due to the rapid decrease of pressure in
the distribution network, water only could flow into underground tanks at households, but
could not flow up to higher water tanks by itself. In addition, quality of supplied water at
households was not guaranteed according to sanitation standards, although the quality of
treated water from treatment plants could meet the standards of supplied water. The cause
is that water is distributed in pipes with low pressure or without pressure or even negative
pressure, and connections are broken. These causes could lead to the situation in which
water easily is filtrated when flowing in the pipes. When the inside pressure increases so
adequately that water can flow in the pipes by itself (higher than 0.6 m/s), sediments
staying long in the pipe systems can flow pipes too and decreases water quality when
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supplying to households. According to the survey results, at present there are around
50% of distribution networks to meet standards of drinking water.
In Hanoi City, urban areas are mainly served with underground water. Most
amounts of underground water are exploited to serve central areas in the city, including
districts and suburb areas in the South West of Red River. Since the decade of 90s,
threats to underground water source were reported, including reduction of water level in
wells, reduction of exploited water amount, water pollution and land subsidence.
Therefore, the city government has banned new exploitation of underground water inside
the city and oriented that exploitation and usage of underground water inside the city
should be gradually decreased. Water supply development in the coming years will rely
mainly on surface water sources from Da, Red and Duong Rivers. Figure 5 shows the
planning of underground and surface drinking water supply in Ha Noi [9]
Figure 9: Planning of underground and surface drinking water supply in Ha Noi.
Source: http://viwase.vn
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In Hai Phong City, 5 main rivers including Bach Dang, Cam, Lach Tray, Van Uc
and Thai Binh flow through the city to the Gulf of Tonkin. Because these rivers affected
by tides, the main water source of the city is the secondary sub-river, protected from tide
impacts (intrusion of saline water). Culverts to collect raw water are located in suburb
areas and at present, there is no problem of raw water quality. Data of monitoring water
quality collected by Hai Phong DoNRE show that surface water source has sign of
pollution due to wastewater intrusion from domestic activities. The city has to take into
account measures to protect water source in the future.
Thua Thien Hue province and Da Nang City have to apply measures to cope with
salination at raw water intake works. Because these rivers in the provinces have typical
features of rivers in the central region of Vietnam with a large seasonal variation in water
levels, ensuring water supply needs to consider in the view of long-term integrated water
resources management.
Da Den Dam supplies 94% of water source for large urban areas such as Vung
Tau city and Ba Ria Town in Ba Ria - Vung Tau province. In 2010, water level of Da
Den Dam abnormally decreased due to extension of the dry season. Ba Ria – Vung Tau
Water Supply Company has a plan to supply additionally water from a reservoir which
will be built in Ray River to Da Den Dam through an open channel with a distance of 30
km.
Dong Nai River is a huge water source for HCM City, Dong Nai and Binh Duong
provinces. At present, the river serves 74% of raw water source for HCM City, 64% - for
Dong Nai and 87% - for Binh Duong. However, some parameters of raw water quality
exceed permissible limits for Type A of the national standards on surface water - QCVN
08:2008/BTNMT. With water source from Dong Nai River, water treatment process
allows to meet standards for domestic water and drinking water in the urban areas.
However, if intake points of raw water collection are impacted by salination due to the
impacts from climate change, it is very difficult to ensure water quality. At raw water
intake works in Sai Gon River, the risk of water pollution became very serious. HCM
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City government has considered moving raw water intake works in Sai Gon River to a
farther location in the upstream area, at lake Dau Tieng in Tay Ninh province. Figure 10
shows the B.O.O Thu Duc drinking water treatment plant in HCM city.
Figure 10: B.O.O Thu Duc Drinking water treatment plant in HCM city (Source:
http://cii.com.vn)
4. RURAL AND HOUSEHOLD WATER SUPPLY
4.1. Rural water supply
Vietnam has performed well in moving towards universal water supply, increasing
access to improved drinking water sources from 62% in 1990 to 95% in 2012.1 In rural
areas there are still challenges to increasing access to piped water supply; the access rate
is 9% compared with 61% in urban areas. Expanding piped water access is essential if the
government is to meet its targets and provide all rural households with access to 60 liters
of clean water per person per day, universal access to hygienic latrines and suitably
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improved personal hygiene. Private operators and communes play a significant role in
building and operating most piped water systems in rural areas [14]. According to the
material of the National Target Programme for Rural Water Supply and Sanitation in
Phase 3 (2011 – 2015), by 2010, a total rural population using sanitary water was
48,752,457, increasing 8,630,000 people in comparison to the end of 2005. The rate of
rural population having access to sanitary water increased from 62% to 80%, lower than
planned 5% and an average increase of 3.6%/year, in which the rate of rural people used
domestic water meeting Vietnamese standard QCVN 02/2009: BYT or higher is 40%, 10
% less than planned. In 7 ecological economic zones, South East area has the rate of rural
population having access to sanitary water of 90%, 10% higher than the national average
rate. The lowest rate 72% was in the West Highland area and 73% in the Central North,
lower than the average of 8% [2]
Some advances in technological science in water supply appropriate to
topographical, meteorological and hydrographic conditions of the locality were applied.
In the small scaled water supply, water treatment technology and techniques were
renovated such as aeration system for removal of iron and arsenic from drilled wells
using underground water in the shallow aquifers (Figure 11). A lot of synchronized
equipment made of different materials to treat water were introduced and applied
throughout the country (Figure 12). Some centralized water supply schemes applied
automatic filtration technology without valves, chemical treatment (for removing iron
arsenic, and manganese and handling hardness etc.), inverter pumping systems, IT
systems in operation management etc. Technology of hanging ponds was renovated with
a larger scope and higher quality to contribute to solving scarcity of water source in the
mountainous and hilly areas in dry seasons When natural disasters occur, localities used
chloramine B and Aquatab, Pur bag etc. to treat water for drinking and cooking purposes
[2]
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Figure 11: Conventional aeration system in rural water treatment plant (Source:
http://bnews.vn )
Figure 12: Advanced aeration and filter tank in rural water treatment plant (Source
http://hanoimoi.com.vn)
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4.2. Household water supply
A wide variety of containers - from traditional ceramic jars to plastic buckets - are
used to store drinking water in homes. Urban and peri-urban households are more likely
to store water in plastic buckets; these range in size from 20 to 220 liters. The containers
are covered with lids to protect the water inside from insects and contamination. Women
and girls are responsible for collecting, storing, and boiling water in almost all
households, as well as for cleaning the water storage containers. In parts of northern and
central Vietnam that experience extended dry periods, households in both peri-urban and
rural areas build large brick and cement tanks to collect rainwater during the wet season.
These hold three to ten cubic meters of water. Because piped water systems do not
necessarily operate all day or every day, some urban households store tap water in 1,000-
liter plastic or stainless steel tanks (Figure 13) [15]. In addition, urban households
nowadays concern about their piped water quality so that they often install the point-of-
use treatment facility such as RO machine in their kitchen (Figure 14)
Figure 13: Household water storage tank in Vietnam (Source: http://www.pbase.com)
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Figure 15: RO Water treatment installed in household kitchen(Source:
https://news.zing.vn)
5. INDUSTRIAL WATER SUPPLY
Industrial water supply occupies about 14% of total water supply in Vietnam
(Figure 16). Table 4, 5 show planning for industrial water supply in terms of quantity in
Thai Nguyen Provinces and Vinh Phuc Province, respectively. Most of industrial zone
have the own water treatment plant (Figure 17). Some industrial zone buy water from
urban water supply company.
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Figure 16: Proportional water supply in Vietnam. (Source: https://biinform.com )
Table 4: Planning of industrial water supply in Thai Nguyen Provinces (Source:
Decision:2546/QĐ-UBND Thai Nguyen date of 29/11/2013)
No Industrial Zone Water demand (m3/d)
2012 2020 2025 2050
1 Song Cong I IZ 800 4.400 5.700 6.300
2 Song Cong II IZ - 3.600 5.400 7.200
3 Quyet Thang IZ - 3.500 5.200 5.800
4 Diem Thuy IZ - 3.500 7.000 10.100
5 Nam Pho Yen IZ 500 3.500 4.900 5.800
6 Yen Binh IZ - 20.000 45.000 62.005
Total 1.300 38.500 73.200 97.205
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Table 5: Planning of Vinh Phuc Provincial water supply (including industrial water
supply) (source: Decision 3818/QĐ-UBND Vinh Phuc, date 29/12/2014)
No Demand Average water usage Maximum water usage
2020 2030 2020 2030
1 Domestic water 100.000 274.000 120.000 329.000
2 Industrial water 89.000 161.000 89.000 161.000
3 Commercial water 46.000 150.000 56.000 179.000
4 Non-revenue water 29.000 73.000 35.000 87.000
Total 264.000 658.000 299.000 757.000
Figure 17: Water treatment plant in Yen Phong IZ, Bac Ninh Province (Source:
http://www.vicen.vn)
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6. THE RECENT TRENDS
6.1. The legal framework
The Government issued the Decree No 117/2007/ND-CP dated July 11, 2007 on
drinking water production, supply and consumption including activities in production,
supply and consumption in centralized water supply systems in urban areas, rural areas,
industrial parks, export processing zones, high-tech zones and economic areas
(commonly called industrial zones). This decree stipulated rights and obligations of
organizations, individuals and households taking part in activities related to production,
supply and consumption of drinking water in Vietnam. After a short time of application,
the Decree No 124/2011 ND-CP dated December 28, 2011 to amend and update the
Decree No 117/2007/ND-CP on production, supply and consumption of drinking water
was timely issued. In 2009, Vietnamese Government updated orientations for
development of urban water supply sector. The Decision No 1929/QD-TTg dated
November 20, 2009 described the orientation for development of water supply sector in
Vietnam in urban areas and industrial parks by the year 2005, the vision to 2050. The
process of urban water supply development was studied to meet 100% of the demand for
water use with a norm of water usage of 120 L/capita/day and reduction of non-revenue
water down to 15% and 24 hours/day water supply service in all urban areas in Vietnam
up to the year 2025 [2]. Recently, the Government updated Orientation via Decision No.
2502/QD-TTg dated December 22, 2016. The most updated Orientation has some
significant points such as public health and livelihood security, improvement of well-
being, support the low-income group and special remote area, safe water supply in the
context of climate change, prioritize surface water and gradually reduce groundwater etc.
The National Orientation Plan and later government decisions have set in motion a
fundamental process of change from centralized sector management to a system in which
the national Government retains responsibility for policy making, sector monitoring, and
facilitation, and local governments assume asset ownership and responsibility for
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providing WSS services. Decentralization has fundamentally changed the way the sector
is managed [19]
6.2. Equitization of the water sector
State-owned water enterprises were restructured and granted autonomy in
financial management and independence. Equitization of infrastructure management
organizations is a significant step forward in improving the autonomy and accountability
of businesses. It also paves the way for the involvement of the private sector and foreign
investment in water supply services. Socializing the provision of infrastructure services in
general and water supply in particular has many benefits: attract more financial resources;
raise the efficiency of construction and operation investment, improve the quality of
services; create a transparent and attractive business environment for domestic and
foreign private investment in each economic sector. Competition is the strongest
mechanism to improve the efficiency of water supply and drainage services. Competition
creates the motivation for businesses to reduce costs to meet the needs of users and to
apply new technology when they occur [19].
6.3. The technological aspect
Some drinking water treatment plants have been invested significantly in terms of
advanced technologies. Di An drinking water treatment plant in Binh Duong city and Tan
Hiep drinking water treatment appear to be typical examples. In Di An WTP, the
treatment processes are shown in Figure 18. In chemical mixing chamber, Poly-
aluminium chloride (PAC) and Lime (Figure 19) is added in the water pumped from the
primary pumping station in this tank. The SCADA (Supervisory Control and Data
Acquisition) (Figure 20) system receives the signal from pH and Turbidity meter
(installed directly in this tank) and then automatically calculates and apply the chemical
dose. Table 6 shows some aspects of water service management posing threat
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Figure 18: Treatment processes in Di An Water treatment plant
Figure 19: Chemical mixing tank [19]
Figure 20: SCADA system [19]
Table 6: Aspects of water service management posing threat
Problems Causes Solution
High turbidity in
settled water
High turbidity in river
water in rainy season
Check and adjust PAC
concentration
Not enough PAC
concentration, short HRT
Change HRT
High turbidity in
filtered water
The filter media gets
clogged
Conduct the backwash step
High filtration rate Check the filtration rate
Increase the number of filtration
tank in the operation mode
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High Alkalinity in
treated water
Low pH in river water
Exceed PAC in use
Change the PAC concentration
Algae grow in
filtration tank
Warm weather Add Chlorine
High P and N concentration Check the N, P concentration in
water
The recent investment made and achievements for the plant’s improvement
include:
Di An WTP 2 is been constructed to meet the rising demand. The
construction is being carried out in two phases:
Phase 1 : capacity 50,000 m3/d – completed
Phase 2: capacity 100,000 m3/d
The filter media is replaced every 10 years
Constructed a micro electricity generator, to prevent power cut off
Before the year of 2000, the plant used vertical sedimentation tank. After
2000, it was changed to horizontal shape
The DAWTP has a decentralized complain office
99 % are satisfied with the service (water quality, water pressure, price)
Most of the complaint issue are broken pipe and water meter problem
In Tan Hiep WTP, the treatment processes are shown in Figure 21 [20]
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Figure 21: Treatment processes in Tan Hiep Water Treatment Plant [20]
The decline in water level and the increase of saline intrusion is complicating the
water supply system. It creates difficulty as most WTPs are not able to handle salt water.
In the dry season, when salinity of the Saigon River increases up to 350 mg/L, Tan Hiep
WTP needs to shut down temporarily. It otherwise causes interruption of raw water and
clean water pumps (i.e. vibration), errors of inverter control software and damaged
devices (valves, chemical dosing system). In the dry season, filter blockage happens
caused by the growth of algae in the filter tank. The phenomenon of floating sludge in
sedimentation tank also occurs (due to large amount of sediment, adhesive and uplift
sludge due to air bubbles generated from the anaerobic decomposition of organic
components in the sludge). It has been reported that the quality of drinking water source
of Saigon River has been deteriorating rapidly due to water pollution generated from
human activities in the upstream basin catchment (COD concentration of 8.08 – 13.82
mg/L). Particularly, high manganese concentration creates the sedimentation during
water distribution pipes after handling at Tan Hiep WTP. To enhance the efficiency of
manganese treatment, the plant uses chlorine to pre-oxidized water before entering the
flocculation, sedimentation and filtration tanks. However, high ammonia, iron, organic
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(COD, TOC) concentration in Saigon river water (many times excess regulations
permitting) lead to a significant increase in chlorine consumption for pre- and post-
chlorination. Also, due to the high chlorine use along with the presence of natural organic
matters in water, the formation ability of the disinfection by-products (DBPs) at Tan Hiep
WTP increases. Additionally, the use of chlorine disinfection chemicals at the end pipes
lead to risk incurring DBPs concentration in treated water
In the existing water collection system at filter tank, it is likely to appear the dead
spots due to the filter material layer. Therefore, the WTP is implementing the
improvement of the filter with higher advantage HDPE filter technology (Figure 22)
Figure 22: Recent changes in filter tanks in Tan Hiep water treatment plant [20]
6.4. The climate change and environment aspect
By the end of 2014, the phenomenon of El Nino has impacted our country, causing
the high temperature, lack of rainfall, causing drought, saline intrusion, causing severe
damage and continues to seriously threaten production and people's lives. Severely
affected areas are the South Central Coast, the Central Highlands, the South East and the
Mekong Delta. Particularly in the Mekong Delta, the region is currently most severely
affected by droughts, saline intrusion and continues to be affected in the future. At the
same time, the salinity intrusion into the mainland is accelerating, and the salinity of the
rivers is high.Hence, the fresh water source is scarce causing the water shortage for
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production and drinking water. About 250,000 households with over 1.3 million people
in Mekong delta had the shortage of water during the drought in May 2016 [21].
In particular, by the end of 2015 and the first months of 2016, the salinity intrusion
in the Mekong Delta has been most heavily evaluated in the last 100 years. Since
February, salinity has remained high and serious. In the Tien and Hau rivers, the salinity
is above 45 ‰, penetrating deep 70 km from the river mouth, even some places up to 85
km. From the end of 2015 up to now, all 13 provinces in the Mekong Delta have been
affected by saline intrusion, including 11 out of 13 provinces reporting drought and saline
intrusion, including Long An, Tien Giang, Tra Vinh, Soc Trang, Bac Lieu, Ca Mau, Kien
Giang, Can Tho, Hau Giang, Ninh Thuan [22], [23]
Figure 18: Saline intrusion in the Mekong Delta (Source:Van Pham Dang Tri)
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7. OPPORTUNITIES FOR COOPERATION
7.1. Public investment
The Circular 08/2012/TT-BXD signed on 21/11/2012 regarding the
implementation of safe water supply has guided the water supply utilities to improve their
services significantly as long as provides the orientation for investment. According to
that, the requirement on assurance of safe water supply are:
Maintaining water pressure, providing stable and sufficient water and
ensuring feed water quality according to prescribed standards.
Having solutions to cope with the unusual incidents, threats and risks which
can occur in the entire production process and supply of clean water from sources to
customer
Contributing to the protection of public health, reduction of water-related
diseases, prevention of epidemic diseases and socio-economic development
Contributing to reduction of the rate of loss, saving of water sources and
environmental protection.
In addition, the Circular describes in detail the content of safe water supply plan
by particularly actions, which can be found in reference number [24]
Based on the guideline from Circular, many big cities have approved their own
Safe Water Supply Plan. For example The Ha Noi People’s Committee has recently
issued Plan No. 148/KH-UBND on guaranteeing water supply and preventing loss of
water in the city in the period of 2017 to 2020 [25]. In particular, Ha Noi will invest to
speed up the progress of ongoing water projects and strive to complete them by 2020.
They are projects on building Duong Noi Water Plant in Ha Dong district, with capacity
of 30,000 cubic meters per day night (to be completed in 2017); project on increasing
capacity of Bac Thang Long - Van Tri Water Plant to 150,000 cubic meters per day night,
of which surface water 130,000 cubic meters per day night; project on building Red River
surface water supply system, capacity of 300,000 cubic meters per day night; project on
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building Duong River surface water supply system with capacity 300,000 cubic meters
per day night, of which 240,000 cubic meters per day night for Ha Noi; project on
building water supply system for Son Tay - Hoa Lac - Xuan Mai - Mieu Mon - Ha Noi -
Ha Dong (second phase), with capacity of 600,000 cubic meters per day night. The city
also aims to develop water supply network from concentrated water source of Ha Noi in
accordance with construction and investment progress of water supply plants, thus
meeting demand for water and water quality. Accordingly, Ha Noi will build water
transmission line No. 2 to convey water from Da River, transmission line along National
Road 32, National Road 21, National Road 21B, road connecting Phuc Tho and Chuc
Son, and Ring Road 4; invest in water supply and distribution network for all communes
using water from the city’s concentrated water supply system, and pumping stations in
Tay Mo, Soc Son, Xuan Mai, Phu Xuyen, Son Tay, Phuc Tho, Kim Bai, Chuc Son and
Ba Vi. Furthermore, Ha Noi will develop rural water supply system from city’s
concentrated water source, striving to provide water to around 2,205,781 people in 235
communes (equivalent to 551,445 households); build local water supply model with
modern technology to provide water to around 513,571 people (equivalent to 128,392
households) in disadvantaged areas in Soc Son, Ba Vi, My Duc, Ung Hoa, Chuong My,
Thuong Tin and Phu Xuyen suburban districts, which are not connected to the city’s
concentrated water supply system yet; implement rural water supply projects with
investment of the private sector, which are approved in principal by the Municipal
People’s Committee (20 projects on rural water supply, which will provide water to
180.828 households in 75 communes); call for investment of the private sector in rural
water supply network, which use water from city’s concentrated water supply system.
The public media on recent investment on water treatment plants can be found in
references number [26], [27], [28].
In term of management, currently, the water quality parameters are well-monitored
in treatment plant by SCADA system. However, after being pumped to the pipeline
network, only the flowrate and pressure data have been measured by automatic sensors
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and sending to the managers. The essential quality parameters such as pH, turbidity,
residual chlorine etc. are not ignored. Therefore, in order to improve the service quality,
the Vietnamese water utilities have to gradually invest their resources to address this
issue.
7.2. Private investment
With the rising concerns of people about the quality of public drinking water,
more and more real estate and housing investors have equipped the in-situ treatment
facilities to provide drinkable tap water for their resident such as EcoLife Capitol, The
Golden Stars etc. These private investors have cooperated with international utilities
(such as Watts Water Technologies for Golden Stars) to apply advanced technologies,
mainly UF, RO (Figure 19)
Figure 19: UF water treatment facilities at The Green Stars Residence, District 7 HCM
city (Source: https://thegreenstar.org)
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Over the years, the water sector has consistently received the attention of domestic
and foreign businesses, as well as investment funds. In that context, Decision 1232/QD-
TTg issued on August 17, 2017 announced the list of state capital outflows by 2020,
which opened up a great opportunity to control and dominate the water sector. According
to this decision, in 3 years, from 2017 to 2019, the government will proceed gradually
divesting of 57 companies in the water supply and drainage sector, stretching from Hau
Giang to Lang Son. Of these, 24 are sold with more than 50% of chartered capital, while
the rest 33 companies will divest at a lower rate.
The most notable feature of this portfolio is the sale of a 98% stake in Vietnam
Water and Environmental Investment Corporation (Viwaseen). It is one of the leading
consulting and constructing companies in the field of water supply and drainage
infrastructure construction. With the dominating ratio of 10 water supply and sewerage
construction companies, including Waseco Water Supply and Sewerage Construction and
Investment (Waseco), owning Viwaseen will provide the opportunity to dominate the
construction segment. Water infrastructure in the two largest cities of Hanoi and Ho Chi
Minh City.
In addition, there are 47 companies operating in the water supply and drainage
sector. Their existing pipeline system will facilitate the transfer of water, cost savings and
the ability to successfully gain market share for future acquirers. Accordingly, 10 clean
water companies on the list of divestments in key provinces such as Bac Giang, Hai
Duong, Hoa Binh, Ninh Binh and Vinh Phuc are big opportunities for clean water
businesses. [29]. Estimated investment demand for urban water supply in Vietnam in the
period 2016 - 2020 is 72,000 billion VND, equivalent to 3.3 billion USD.
According to the Department of Technical Infrastructure, the next phase,
investments will focus on works such as raw water pipelines, transmission pipelines,
transport pipelines and distribution pipelines.
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In the coming time, the Ministry of Construction will support the implementation
of PPP projects in the field of water supply, drainage and solid waste treatment in urban
areas. One of the issues that needs to be resolved in the short term is to establish adequate
mechanisms for the PPP project in this area and to have a suitable counterpart fund to
contribute to the state budget portion of the PPP project.
In the context of limited ODA and government budget, in order to meet the
demand for investment capital for development of water supply, the target of mobilizing
private capital, domestic and foreign enterprises is the main source of capital. investment
and development of water supply [30].
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REFERENCES
[1]https://www.wsp.org/sites/wsp.org/files/publications/WSP-Vietnam-WSS-Turning-
Finance-into-Service-for-the-Future.pdf
[2]http://www.wpro.who.int/vietnam/topics/water_sanitation/watsan_sector_report_vietn
am_2011.pdf
[3]http://hawacom.vn/wp-content/uploads/2015/09/H-8.11-QH-MLCN-nam-2030-in-A3-
NGAY-15-4-2013-Model.jpg
[4] http://www.vjol.info/index.php/ssirev/article/viewFile/8461/7838.
[5] http://www.wepa-db.net/pdf/1003forum/2_vn_maitrongnhuan.pdf.
[6] http://www.narbo.jp/data/01_events/materials/tc01_cr_vietnam03.pdf.
[7] http://nguyenthanhmy.com/courses/GOOD-Mekong-Water-Resource-2011.pdf.
[8] https://www.adb.org/sites/default/files/project-document/72257/25271-vie-tar.pdf
[9] http://www.wepa-db.net/pdf/0712forum/paper04.pdf.
[10]https://pub.iges.or.jp/pub_file/06chapter3-
3hochiminhpdf/download?token=Kd2USYtt.
[11]https://www.adb.org/sites/default/files/linked-documents/cps-vie-2012-2015-ssa-
05.pdf.
[12] http://www.biwase.com.vn/QLChung/Index_en.aspx
[13] http://huewaco.com.vn/Default.aspx
[14] https://www.gpoba.org/LL07_VietnamWater
[15]http://en.sapuwa.vn/tin-tuc/specialized-news/consumer-and-market-research-on-
household-water-treatment-productsin-vietnam-part-2.html
[16]https://www.oecd.org/countries/vietnam/47148740.pdf
[17].http://www.xaydung.gov.vn/en/web/guest/thong-tin-tu-lieu/-/tin-chi-
tiet/ek4I/86/26705/co-hoi-va-thach-thuc-doi-voi-nganh-cap-thoat-nuoc-trong-nen-kinh-
te-thi-truong.html
[19]http://www.jwrc-net.or.jp/aswin/en/newtap/report/NewTap_023.pdf.
[20]http://www.jwrc-net.or.jp/aswin/en/newtap/report/NewTap_011.pdf.
[21]http://english.vietnamnet.vn/fms/environment/159405/water-in-mekong-river-delta-
at-risk-of-arsenic-contamination.html
[22].http://tiengiang.gov.vn/SNN/42/668/1125/93690/Tin-tuc----su-kien/CAC-GIAI-
PHAP-KIEM-SOAT-MAN--TRU-NUOC-NGOT-DE-PHUC-VU-SAN-XUAT-VA-
DAN-SINH-VUNG-DBSCL.aspx
[23].https://www.most.gov.vn/vn/tin-tuc/7039/xam-nhap-man-tai-dong-bang-song-cuu-
long---nhung-giai-phap-ung-pho-hieu-qua-trong-dieu-kien-bien-doi-khi-hau.aspx
[24]http://hethongphapluatvietnam.com/circular-no-08-2012-tt-bxd-of-november-21-
2012-guiding-the-implementation-of-safe-water-supply.html
[25]http://english.hanoi.gov.vn/
[26]http://www.vir.com.vn/hanoi-plans-255-million-water-plant-to-reduce-water-
shortage.html
[27]http://www.vitensevidesinternational.com/festive-opening-of-new-water-treatment-
plant-in-soc-trang-vietnam/
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[28]http://www.waterworld.com/articles/wwi/2016/01/vietnam-potable-water-treatment-
plant-expansion-includes-ozone-treatment.html
[29] https://www.baomoi.com/loi-nhu-nganh-cap-thoat-nuoc/c/23319619.epi
[30] http://bnews.vn/3-3-ty-usd-cho-nhu-cau-cap-nuoc-do-thi-tai-viet-nam/4522.html
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ABOUT THE AUTHORS
David Nguyen
Lecturer
Faculty of Environment
Thuy Loi University
175 Tay Son Street, Ha Noi, Vietnam
Email: [email protected]
Daniel Nguyen
Lecturer
Faculty of Water Resources Engineering
Thuy Loi University
175 Tay Son Street, Ha Noi, Vietnam
Email: [email protected]
Paul Smith
International Manager
Advocacy and Industry Department
Australian Water Association ‘
PO Box 222, St Leonards NSW 1590
Email: [email protected]
An Nguyen
International Coordinator
Advocacy and Industry Department
Australian Water Association ‘
PO Box 222, St Leonards NSW 1590
Email: [email protected]