Last update
2025
Summary
Women in Europe for a Common Future (WECF) implemented Bulgaria’s first constructed wetland in Vidrare (Pravets) to treat domestic wastewater from the St. Panteleimon home while building local capacity. The plant is a vertical subsurface-flow reed bed for ~80 PE, combining an 18 m³ two-chamber settling tank with intermittent pumping to a 266 m² planted sand filter split into two beds; treated effluent discharges to a nearby gully. Design: Otterwasser (DE) and Ecoproject (BG); works: Interstroy; funding: German Federal Environment Foundation (DBU). Construction ran Oct 2010–Apr 2011; the facility was officially inaugurated on 29 April 2011. O&M is handled by trained staff from the home; reported investment was about €45,000 (+≈10% for planning). The site has served as a national demonstration/education example and continues to be cited by Bulgarian authorities (e.g., Ramsar COP14 National Report, 2022).
Position
Latitude
42.99305
Longitude
24.01
Project
NWRM
National Id
Bulgaria_06
Installation date
2011-04
Implementation Status
Contact
REC
RBD code
BG1000
Transboundary
0
Photo gallery
Location of the project
St. Panteleimon residential home, ul. “Georgi Dimitrov” 1, 2166 Vidrare, Pravets Municipality, Sofia Province. Within the village, on the left (low) bank area of the Malki Iskar river; road access via the municipal route III-308 Kalugerovo–Vidrare–Djurovo, which connects to national road I-3 (E83).
NUTS Code
BG41 - Югозападен (Yugozapaden)
Project's objectives
Raise awareness and build capacity among professionals and citizens on extensive/low-tech wastewater treatment (train the Home’s appointed operator; publish materials; hold a national seminar/visit).
Provide on-site treatment for the Home’s domestic wastewater (kitchen, toilets, laundry) to “improve the existing situation,” by installing a constructed wetland on the Home’s plot.
Provide on-site treatment for the Home’s domestic wastewater (kitchen, toilets, laundry) to “improve the existing situation,” by installing a constructed wetland on the Home’s plot.
Involved Partners
| Authority type | Authority name | Role | Comments |
|---|---|---|---|
Climate zone
warm temperate moist
Temperature
11
Precipitation
507
Annual rainfall range
300 - 600 mm
Imperviousness
100
Elevation range
314 m
Slope range
5.0
Water bodies: Ecological Status
Moderate
Water bodies: Chemical Status
Good
Project scale
Micro
Project scale specification
Site-specific, on-plot constructed wetland at the St. Panteleimon home in Vidrare (~80 PE), treating wastewater from a single institution within village bounds. It’s a localized intervention (design, construction, and O&M confined to one property), with no basin-wide planning or regional infrastructure—fully consistent with “Micro-scale” in your scheme.
Performance timescale
< 1 year
Area subject to Land use change or Management/Practice change (ha)
0,0399999991059303
Size
0,0659999996423721
Size unit
ha
Presence of many underground cables and pipes, which had not been mentioned in previous documentation.
Existing sewerage, gully and river as receiving water, slope in the yard and available space
Total cost
€45,000
Costs total information
Investment costs: excavation and piping(12000), per-treatment step (6000); Soil filter: liner(6000), grave and sand(7000), pipes (9500), pumps (4500)
Costs investment
45000
Costs operational information
The operation and maintenance costs depends on the local cost of energy and staff. Require time and energy supply: time 1.5h/week; energy 2kWh/d; sludge disposal 36m3/yr
Financing authorities
Type of funding
Other
Comments
DBU grant for the overall project (demo plant + training + conference + publications)
Type of funding
Local funds
Compensations
0
Policy context
Ground water contamination due to untreated sewage discharge
Land ownership
The wetland was built in the yard of the St. Panteleimon home, which is part of Pravets Municipality → the land is municipal.
Community involvment
Yes
Design consultation activity
| Activity stage | Name | Key issues | Comments |
|---|---|---|---|
|
Implementation phase
|
Seminar
|
November 19th, 2010; 25 participants; Related to the construction of the first constructed wetland in bulgaria
|
|
|
Implementation phase
|
National Conference
|
April 29th, 2011 in Gran Hotel Sofia; Presenting constructed wetlands as a sustainable and cost-effective wastewater treatment system
|
Policy target
| Target purpose |
|---|
|
Pollutants Removal
|
Target Remarks
Create Bulgaria’s first CW as a demonstrator that municipalities could replicate; make it visibly “attractive.”
Policy pressure
| Pressure directive | Relevant pressure |
|---|
Policy impact
| Impact directive | Relevant impact |
|---|
Requirement directive
| Requirement directive | Specification |
|---|
Contractual arrangements
0
| Arrangement type | Responsibility | Role | Name | Comments |
|---|
Part of wider plan
0
Wider plan type
| Wider plan type | Wider plan focus | Name | Comments |
|---|
Self-monitoring consists of an operation diary, recording water consumption and visual discharge checks, plus effluent sampling at a frequency set by the water authority.
The case study prescribes “sampling of the discharged water according to the regulations of the water authority” and does not fix a Vidrare-specific list; it references the EU Urban Waste Water Treatment Directive for typical compliance parameters (BOD₅, COD, suspended solids) and notes pathogen indicators can be reduced, while the design states nutrient removal was not required at Vidrare—so nutrients would only be monitored if the authority asked for them.
Maintenance
Routine O&M is done on-site by an appointed staff member of the St. Panteleimon home (trained/instructed by Otterwasser), following a daily/weekly/annual plan.
Edge of Field/Plot
Difference between samples in inflow and outflow
Energy demand: operation listed as ~2 kWh/day for pumps (≈750 kWh/yr) = low-cost and low carbon emissions.
Public health / service quality
Public health / service quality
Retained water
272
Retained water unit
m3/month
Increased water storage
272
Increased water storage unit
m3/month
Water quality overall improvements
Positive impact-WQ improvement
Information on Water quality overall improvements
~70–90 % removal of BOD/COD/SS and 1–3-log pathogen reduction; nutrient removal was not a design requirement for Vidrare.
Soil quality overall soil improvements
Not relevant for this application
Ecosystem impact climate regulation
Not relevant for the specific application
Key lessons
Small, on-plot constructed wetlands work well as demonstrators. As the NWRM page notes, “Small scale constructed wetland for water treatment could be good demonstration of specific type of NWRM with direct economic and water quality benefits. Constructed wetlands are so far rarely used in spite of the successful pilot tests.” Vidrare confirms this adoption gap: the plant functions as a showcase more than a widely replicated model.
Early and hands-on capacity building is decisive. Training a named on-site operator, providing an operations diary, and agreeing simple daily/weekly/annual tasks made routine O&M feasible for a municipal care home with limited technical staff.
Permitting and administration are often the critical path. Time was spent aligning authorities with an unfamiliar technology; proactive engagement and clear responsibilities helped unlock approvals and clarify who monitors what, when.
Design details that prevent failure matter more than “optimal” performance tweaks. A robust pre-treatment, a fully lined VSSF bed, separation from stormwater, pumps with simple controls, and an emergency overflow plan reduced risks like hydraulic short-circuiting, rain ingress, or power-failure spills.
Expect and budget for minor “punch-list” corrections after start-up. Small fixes—drainage to keep runoff out, cleaning/adjusting outlet shafts, sealing—are normal and should be planned into commissioning, with roles shared between contractor and owner.
Economics favour low running costs over very low capex. With roughly €45k investment, ~1.5 h/week of labour and ~2 kWh/day electricity, the whole-life burden is modest for an institution-scale facility, making the solution attractive where operational simplicity is valued.
Evidence still needs structured monitoring. The case demonstrates likely improvements in effluent quality, but site-specific lab series are scarce; future replicas should lock in a simple, authority-aligned monitoring plan to generate data beyond visual checks.
Replication should target similar institutional settings. Municipal homes, schools, or small clusters with available yard space and a willing local operator are the sweet spot; nutrient polishing can be added only if the receiving context requires it.
Early and hands-on capacity building is decisive. Training a named on-site operator, providing an operations diary, and agreeing simple daily/weekly/annual tasks made routine O&M feasible for a municipal care home with limited technical staff.
Permitting and administration are often the critical path. Time was spent aligning authorities with an unfamiliar technology; proactive engagement and clear responsibilities helped unlock approvals and clarify who monitors what, when.
Design details that prevent failure matter more than “optimal” performance tweaks. A robust pre-treatment, a fully lined VSSF bed, separation from stormwater, pumps with simple controls, and an emergency overflow plan reduced risks like hydraulic short-circuiting, rain ingress, or power-failure spills.
Expect and budget for minor “punch-list” corrections after start-up. Small fixes—drainage to keep runoff out, cleaning/adjusting outlet shafts, sealing—are normal and should be planned into commissioning, with roles shared between contractor and owner.
Economics favour low running costs over very low capex. With roughly €45k investment, ~1.5 h/week of labour and ~2 kWh/day electricity, the whole-life burden is modest for an institution-scale facility, making the solution attractive where operational simplicity is valued.
Evidence still needs structured monitoring. The case demonstrates likely improvements in effluent quality, but site-specific lab series are scarce; future replicas should lock in a simple, authority-aligned monitoring plan to generate data beyond visual checks.
Replication should target similar institutional settings. Municipal homes, schools, or small clusters with available yard space and a willing local operator are the sweet spot; nutrient polishing can be added only if the receiving context requires it.
Success factor(s)
| Success factor type | Success factor role | Comments | Order |
|---|---|---|---|
|
Financing possibilities
|
main factor
|
<p>In rural areas, there is a lack of financial, technical and staff resources, thus low-tech, cost-efficient and sustainable wastewater management systemas are needed</p>
|
1
|
|
Attitude of relevant stakeholders
|
secondary factor
|
2
|
Driver
| Driver type | Driver role | Comments | Order |
|---|---|---|---|
|
Organisation committed to it
|
main driver
|
WECF NGO
|
1
|
Transferability
Highly transferable to small institutions with yard space and low-tech O&M needs. Key cautions: secure permits early; size for ~80 PE (or adapt); ensure robust pre-treatment; keep stormwater out; use a lined VSSF bed; appoint/train an on-site operator; plan simple monitoring and sludge disposal; check power reliability and receiving-water requirements (nutrient limits) before design.
English