sustainable urban sanitation solutions in ethiopia: … · 2020. 12. 4. · characterization and...
TRANSCRIPT
CHARACTERIZATION AND VALORIZATION OF FECAL FOR
DEVELOPMENT OF SUSTAINABLE URBAN SANITATION IN
ETHIOPIA
SUSTAINABLE URBAN SANITATION SOLUTIONS IN
ETHIOPIA: FROM CONTAINMENT TO RESOURCE
RECOVERY ORIENTED SANITATION
6TH INTERNATIONAL DRY TOILET CONFERENCE.
BY TAMENE HAILU, ETHIOPIA
Tampere, Finland.
August 22 to 26, 2018
Out line
Introduction
Research Objective
Research material and methods
Result and discussion
Conclusion and recommendation
Future prospect
Introduction
Sub-Saharan Africa (SSA) had achieved only 30% sanitation coverage by 2015, with only a 4 percentage point increase from 1990 (WHO, 2015).
Lack of access to proper sanitation that hygienically separates fecal waste from human contact is a serious concern (UN water, 2014).
The practice of open defecation is a primary cause of fecal borne disease transmission, with children being the most vulnerable.
Reducing by half the proportion of untreated wastewater has been established as a target in the UN’s recently released Agenda 2030 for sustainable development (Goal 6.3).
Con…
In most communities of SSA, the collected fecal
sludge from OSS is dumped back into the
environment without any treatment (Baum et al., 20l3).
In rapidly expanding urban areas in SSA, FSM
represents a growing challenge in posing significant
negative public health and environmental risks
(Cairncross et al., 2010)
FSM, the most important sanitation element, is also
largely ignored in the global estimation of improved
sanitation coverage (Beyene et al., 2015).
Characterization of fecal matter is the prerequisite to
understand which type of OSS technology applicable
effectively in particular geographic location and culture
Urban Sanitation Overview (JMP)
5
0
5
10
15
20
1990 2000 2010 2015
improved
Urb
an P
op
ula
tion (m
illions
) us
ing
unimproved
shared
Open defecation
Data for Ethiopia
Con…
Addis Ababa is Ethiopia’s rapidly growing capital city and with
more than 3 million residents it is one of the largest cities in
Africa.
Over 80% of Addis Ababa’s population lives in slum districts
with very poor housing, which are overcrowded and have little
or no urban service provision (UN-Habitat, 2005, 2014).
Only a small proportion of the city is served by conventional
sewerage systems, while most areas rely upon on-site
sanitation (Beyene et al., 2015).
Most households (about 75%) have pit latrines that are either
emptied when full or discharge to open drains; and a
significant minority (about 5%) resort to open defecation
(CSA, 2005)
Fecal sludge management system of Addis Ababa
Containment
Flush toilet
Septic tank
Dry toilet
Emptying
Sewer system
Vacuum truck
Transport
Gravity
Truck
Treatment
Stabilization pond
FS dying beds
Recycle &
disposal
Partial treated FS discharged
into rivers
Dry FS disposed into
land
Residential environment
Open defecation
Growth of URI and Diarrhea in Addis Ababa (2012-2014)
URI Diarrhoea
year Cases %ge of total
top ten cases
Cases %ge of total
top ten cases
2014 361,447 29% 112,948 10%
2013 370,000 27% 102,373 9.3%
2012 223,365 25% 88,009 9.2%
Why On-site Sanitation is Important
Most urban dwellers with
sanitation access use on-site:
<10% of urban Africa has
sewer access
Virtually all poor people use
on-site sanitation – if they
have any sanitation at all
On-site sanitation is rarely
managed as an integrated
system including transport
and treatment, resulting in
major environmental pollution. Sources: Africa Infrastructure Country Diagnostic Background Paper 13 (2008) Elvira Morella, Vivien Foster, and Sudeshna Ghosh Banerjee
UNICEF/WHO Joint Monitoring Program (2015) Progress on Sanitation and Drinking Water: 2015 update and MDG assessment
0%
20%
40%
60%
80%
100%
1 2 3 4 5
Poorest Wealth Quintile
Urb
an A
ccess
to Im
pro
ved
Sa
nita
tion
Thinking outside the box
Business as usual sanitation system could not
able to avoid environmental contamination &
the associated diseases incidence and
prevalence.
Therefore the source recourse recovery
oriented sanitation research is crucial.
Sanitation: for environment, health and
income
Research Objective
General:
To investigate the current system of containment in relation to poor sanitation approach in preventing environmental pollution & promoting health
Specific:
To provide further evidence on the occurrence and survival of pathogens in the fecal sludge of dry pit latrines, and the degree of contamination of the wider environment (soil and water).
To characterize and determine the composition of fecal sludge and estimation of the energy recovery potential, to understand which type of OSS technology is applicable effectively in particular geographic location and culture (the case of Addis Ababa).
To suggest appropriate sanitation solutions for slum area.
Material and methods
This paper presents findings:
Data from :
Secondary sources, project documents, plans and appraisals, National data, JMP and Expert interviews
Analysis of three main surveys: a survey of pit latrines and soils parasite load in terms of
Ascaris Lumbricoids ova.
a survey of water sources including both surface and groundwater sources and their level of fecal contamination.
a survey of pit latrines to assess characteristics of faecal sludge for energy potential in particular geographic location and culture (the case of Addis Ababa).
Survey and assessment of pit latrine
A total of 25 dry pit latrines from 5 sub city in slum areas were sampled
To study the parasite load in terms of AscarisLumbricoids ova
To study the characteristics for resource recovery
Samples were taken from three zones:
top surface to about 0.5 m depth (aerobic degradation zone),
facultative anaerobic zone (0.5 to 1.5 m) and
anaerobic zone(>1.5 meters with samples taken 0.30-0.5 m above the bottom of the pit).
Con…
Parasite load in terms of AscarisLumbricoids ova
in pitlatrine
Using a Sedgwick-Rafter cell, the concentrate was
examined to enumerate the detected ova.
The ova were classified as either
unembroyenated or
embroyenated to the first, second or third larval stage.
The Ascaris ova count was made using the equation:
Ova/g dry wt. = [(NO)*(CV)*(FV)]/ [(SP)*(TS)]
Fecal sludge sampling from dry pit latrines
Sludge & Sediment
Sampling Kits
1 L polyethylene
bottle with airtight
cap Label
Composite sample for
each depth (surface,,
0.5 , 1m, …Bottom)
Our previous plan
It was impossible for us to get this commercial sampler. It is
very expensive (about US$ = 7000.00 excluding vat and
shipping)
Solution: designing and producing new pit sludge
sampler (PSS)
Survey and assessment of soils
A total of seventy samples of soil were taken from
yards or gardens and road banks and assessed
for A. lumbricuides to provide an indication of
contamination and risk.
The samples were taken at accessible and shady
sites without vegetation across the five sub cities.
Sites were selected from areas close to the pit
latrines.
Procedure for assessment of A. lumbricuides was
similar to that used for the sludge samples.
Survey and assessment of water sources
27 Groundwater and 18 surface water samples
were collected and analyzed to provide an
assessment of levels of contamination of water
sources.
Microbial enumeration of water contamination
indicators of human faecal origin(total coliforms
(TC), Faecal coliforms (FC) and E. coli) were
performed using the Membrane Filtration (MF)
technique and
Chemical quality were measured following
standard methods (APHA, 2005).
Con…
4 characteristics for resource recovery
Experiment is conducted to assess the feasibility of energy
and fertilizer recovery from sampled dry pit latrines.
Proximate & ultimate analysis by weight (C, H, N, S, O, Ash,
Moisture, Calorific value, density, particle size)
The proximate analysis and solid content were determined
using gravimetric and bomb calorimeter method following
standard procedures.
The ultimate analysis of the sludge was done using the
PerkinElmer 2400 Series II (Series 2) CHNS/O Elemental
Analyzer.
Result and discussion
1.1 parasite load in terms of AscarisLumbricoids ova in pit latrine
A.lumbricoides counts with show a considerable and significant reduction in
the number of ova within the anaerobic zone compared to the middle
facultative anaerobic and near-surface aerobic zones.
Con…
2. parasite load in terms of AscarisLumbricoids ova in
surface soils
Soil Samples No. of
sample
%
positive
Number of Ascaris ova/100g of soil
Total Embryonated (live)
Yard/garden
soil 50
48
(96%) 28 19 (68%)
Road banks 20 16
(80%) 21 13 (62%)
Con… 3. Microbial contamination indicators of human
fecal origin in water sources 3.1 Water chemistry indicators (Levels of chloride and nitrate)
The concentration of chloride in shallow wells was found to be relatively high with a mean concentration of 41.5±65.2mg/l compared to springs and deep-wells with a mean concentration of 16.0 ± 20.8 mg/l and 15.4±9.0 mg/l respectively.
There was about two folds increase of chloride concentration at the mid-catchment sites and a further doubling in the concentration at the downstream sites.
Both shallow and deep wells were found to be rich in nitrate which suggests that even the deeper aquifer may be contaminated from fecal sludge.
Even the protected spring waters that are usually assumed to be free from contamination were also found to be rich in nitrate.
Con…
3.2 Fecal contamination indicators. About 50% of the deep and shallow well samples
were positive for TC, with similar results for springs
(40%).
While 25% of the samples from deep wells and
50% from shallow wells were positive for both FC
and E.coli.
All surface water samples (100%) were positive
for TC and almost all (with the exception of some
upstream sites) were positive for FC and E. coli.
*
*
*
*
*
0 5 10 15 20 25 30
Human feces briquette (10%
starch)
Human feces char
Hardwood bedding
Coffee Husk char
Raw human feces
Vergine wood
Muncipal mixed waste
Heating Value (MJ/Kg)
FAO briquette heating value standard (22 MJ/kg)
Heating value of human feces and solid fuels compared from
literatures (*)
Theoretical versus experimental calorific value Theoretical CV based on characterization = 18.46 MJ/Kg
Dry raw human feces CV = 17.9 MJ/Kg
Carbonized through slow pyrolysis (Char) = 23.7 MJ/kg
Calorific Value of FS for top, middle, & bottom section of the dry pit latrines
Minimum Calorific value standard = 18 MJ/kg & Wood biomass = 19.8 MJ/Kg
Median =20.92 MJ/Kg
18.83 MJ/Kg
17.80 MJ/Kg
Current knowledge on the sanitation solution
with resource recovery FS has potential market value for fuel, biogas, animal feed, component
in building materials & soil conditioner (Diener et al. 2014)
Business models for faecal sludge management in Sub-Saharan Africa
Biodesil production of fatty acid methyl esters (18 wt%) with other potential
byproducts of sterols, aliphatic alcohols & waxes (Pasture et al. 2014)
Conclusion
There are serious risks related to poor sanitation and improper treatment of faecal waste in Addis Ababa
Fecal contamination of Soils, groundwater and surface waters is shown to be widespread,
The need for proper treatment and disposal of pit latrine wastes is illustrated by the survival of pathogens even in the deep anaerobic zone of pit latrines.
The manufactured feces biochar in this study has met the FAO standards for biochar energy which is 22MJ/kg and comparable to wood biomas (19.8 MJ/kg). Minimizes the cost of access to sanitation
Cost for land for both containment & FSM
Cost for central waste treatment
Cost for healthcare
Recommendations
It is recommended that such results are used with
policy makers to put improved household and urban
sanitation and proper faecal sludge
management(FSM) higher on the agenda.
Development and regulation of FSM technology
and markets
Building capacity – dialogue, systems, guidelines,
institutions, staff, skills…
Standards, benchmarking and accountability
Valorization of Waste for Sustainable FSM
Dry
Biomass
Solid
waste?
Human
excreta
(Fresh &
toilets Pretreatment
Drying + Prop.
Pyrolysis
350-650 0C
Biochar
Characterization
Proximate & ultimate analysis by
weight (C, H, N, S, O, Ash, Moisture,
Calorific value, density, particle size)
Proximate & ultimate analysis by
weight (C, H, N, S, O, Ash, Moisture,
Calorific value, density, particle size)
Characterization
Mass & energy
balance
Conclusion on developing closed-loop sanitation
Future prospect Innovation on alternative sanitation technology
Pilot field scale demonstration of
the closed-loop sanitation
solution
Integrating FSM with solid waste management
Solid waste
Toilet
Publication outputs
References
Bakare, B. F., Foxon, K. M., Brouckaert, C. J., & Buckley, C. A. (2012). Variation in
VIP latrine sludge contents. Water SA, 38(4), 479-486.
FAO, 2011. Methods for Producing Biochar and Advanced Biofuels in Washington
State, USA.
Diener, S., Semiyaga, S., Niwagaba, C et al. (2014). A value proposition: Resource
recovery from faecal sludge—Can it be the driver for improved sanitation?.
Resources, Conservation and Recycling, 88, 32-38.
Pastore, C., Lopez, A., Lotito, V., & Mascolo, G. (2013). Biodiesel from dewatered
wastewater sludge: A two-step process for a more advantageous production.
Chemosphere, 92(6), 667-673.
APHA (2005) Standard methods for examination of water and wastewater. 21th edn.
American Public Health Association, American Water Works Association & the Water
and Environment Federation, Washington, DC.
WHO/UNICEF: Joint Monitoring Programme for Water Supply and Sanitation,
Progress on Sanitation and Drinking Water: 2010 Update. Geneva: World Health
Organization; 2010.
Acknowledgements
Jimma University
SRFA, WRC, South Africa
Ethiopian Ministry of Water, Irrigation & Energy
Addis Ababa City Administration & Residents
Chemistry Department, AAU
Ethiopian Geological Survey Laboratory
Ramboll Finland Community-Led Accelerated WASH (COWASH)
Thank you