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Water and waste water treatment systems of Vistino village

BASE Project - Implementation of the Baltic Sea Action Plan in Russia

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Copyright 2014 Baltic Marine Environment Protection Commission HELCOM

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Table of contents

1.DESCRIPTION OF THE TERRITORY ................................................................................................................ 5 1.1 Location of the territory on maps. ............................................................................................................ 5 1.2 Territory land tenure and condition of general plans ............................................................................... 7 1.3 Objects of natural and cultural heritage and protected areas.................................................................. 8 2. HYDROGRAPHY ............................................................................................................................................ 9 2.1. Resources of underground waters ........................................................................................................... 9 2.2. Resources of surface waters .................................................................................................................. 10 3. DESCRIPTION OF EXISTING WATER SUPLLY AND SEWAGE SYSTEMS OF “VISTINO RURAL SETTLEMENT” 12 3.1. Main information about Vistino ............................................................................................................. 12 3.2. General characteristics of water supply and wastewater systems ........................................................ 13 3.2.1. Characteristics of the water supply network ...................................................................................... 14 3.2.2. Characteristics of the sewage network ............................................................................................... 14 3.2.3. Water consumption volume and wastewater volume ....................................................................... 16 3.2.4. Calculation of infiltration .................................................................................................................... 18 3.2.5. Balance of water supply and sewage systems .................................................................................... 20 3.2.6. Water intake and treatment facilities ................................................................................................. 21 3.2.7. Existing water supply and water treatment process ..................................................................... 22 3.2.8. Proposals for a water purification system ..................................................................................... 24 3.2.9. Waste water treatment facilities ........................................................................................................ 26 3.2.10. Suggestions for a waste treatment system. ...................................................................................... 33 4. FORECASTS OF DEVELOPMENT ............................................................................................................. 34 4.1 Forecast of development Vistino settlement. ......................................................................................... 34 5. TECHNICAL SOLUTIONS AND PLANNING SCHEMES .............................................................................. 36 5.1. Drinking water sources ...................................................................................................................... 36 5.2 Suggestions for water supplay system .................................................................................................... 38 5.2.1. Technical description and basic parameters of the various options ............................................. 39 5.2.2. An assessment of the pipe network in need of refurbishment and recommended method of reconstruction. .............................................................................................................................................. 39 5.2.3. Assessment of the risks and impacts of different options. ........................................................... 40 5.2.4. Comparison of different options in terms of cost and effect ........................................................ 41 6. GUIDELINES ............................................................................................................................................ 44 7. CONCLUSIONS AND RECOMMENDATIONS ........................................................................................... 45 APPENDIX 1. Questionnaire .......................................................................................................................... 46

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INTRODUCTION

This work was based on the technical specifications for the implementation of the survey of water supply and water treatment, as well as wastewater and water treatment systems of Vistino village.

The objectives of this work is:

1. Rational providing consumers with water in sufficient quantity and quality solutions;

2. Ensure full diversion drains and cleaning them up to the standards of surface impoundment;

3. Conservation of natural water conditions and its protection from pollution and contamination.

PURPOSE OF WORK

1. The technical condition of the existing water treatment facilities and wastewater treatment .

1. Based on an assessment of the current situation ‐ how to find a technological solution to ensure the quality of water treatment at household needs and domestic wastewater to achieve performance, satisfying requirements Sanitary 2.1.4.1074‐01 "Drinking water hygiene requirements for water quality of centralized drinking water supply. quality control " and SanPin 2.1.5.980‐00 " Hygienic requirements for surface water " respectively.

2. Determining the possibility of using existing structures of buildings for accommodation and operation of technological equipment. Consideration of possible options for the location of treatment facilities.

3. Justification of the most appropriate choice of water treatment plants and their locations.

4. Determining the status of the existing water supply and sanitation, in order to identify areas requiring full or partial replacement. Trace analysis of networks to determine whether the schema change water and sewage networks and adding new sections of pipeline.

5. Justification most appropriate option trace networks and renovation sites.

SCOPE OF WORK

Water system. sewage Treatment Plants

1. Description of the current situation of water intake and water treatment systems ;

2. Assess the effectiveness of existing treatment facilities ;

3. Visual inspection of construction of the existing building WTP identifying and fixing defects;

4. A visual examination and documentation of existing engineering and manufacturing equipment to the definition of suitability for use in the reconstruction of the WTP ;

5. Documentary examination of existing intake system and water purification ;

6. Selection of the optimal variant reconstruction WTP, with the selection of the main technological equipment. Determining the cost of reconstruction of the enlarged by the proposed options;

7. Drawing conclusions on the results of the survey.

Water system. water supply network

1. Description of the current situation external water supply;

2. Analysis of the networks with the identification of sites for reconstruction;

3. Determine if it need to install new plumbing areas;

4. The final assessment of water supply networks in general proposals and selection of the optimal variant of reconstruction and determination of the enlarged value;


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Drainage system . sewage Treatment Plants

1. Analysis of the current state of treatment facilities;

2. Identify sources of waste water , to determine the possibility of exclusion and localization effluent analysis of chemical composition and quantity of waste generated;

3. Assess the effectiveness of existing treatment facilities on the following criteria: performance ( current and scheduled) , qualitative indicators of the chemical composition of the original and the purified waste water , the state of operating units and assemblies , process technology necessary compliance requirements;

4. Visual inspection of construction of the existing building WWTP identifying and fixing defects;

5. A visual examination and documentation of existing engineering and manufacturing equipment to the definition of suitability for use in the reconstruction of WWTP;

6. Selection of the optimal variant reconstruction WWTP, with the selection of the main technological equipment. Determining the cost of reconstruction of the enlarged by the proposed options;


Drainage system. sewage network

1. Description of the current situation of external networks of wastewater;

2. Analysis of the networks with the identification of sites for reconstruction;

3. Determine if you need to install new drainage areas;

4. The final assessment in general water supply network proposals and selection of the optimal variant of reconstruction and determination of the enlarged value;


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1.DESCRIPTION OF THE TERRITORY 1.1 Location of the territory on maps. Vistino rural settlement is a municipality, a part of Kingiseppskiy district of Leningrad region of the Russian Federation. Here we describe the village Vistino as part of Vistino rural settlement. Number of residents is 821 people. (Census of Population 2010. Rosstat).

Figure 1, 1A. Location of Municipality “Vistino rural settlement” at Baltic sea and Gulf of Finland.

Leningrad region — subject of the Russian Federation, located on the North‐West of the European part of the country, part of the North‐West Federal District and the North‐West Economic Region.

Territory is about 83,908 km², which is 0.49% of the territory of Russia. For this parameter, the region is ranked on the 39th position in the country. From the west to the east region reaches for 500 km, and the longest distance from the north to the south is 320 km.

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Population is about 1 763 924 people. (in accordance with data of 2014 year).

Borders:

from the north — Republic of Karelia

from the east — Vologda region

from the south‐east – Novgorod region

from the south — Pskov region

with St. Petersburg (semi‐enclave)

with European Union: from the west— Estonia and from the north‐west — Finland

From the west the territory is bordering with the Gulf of Finland.

Figure 2. Location of Municipality “Vistino rural settlement” and Kingiseppskiy Municipal District at map of Leningrad region

Kingiseppskiy municipal district is located in the western part of Leningrad region.

District borders:

from the north‐west and north boundary runs along the shore of the Gulf of Finland;

from the east ‐ along the administrative border with Lomonosovskiy and Volosovskiy districts;

from the south ‐ along the administrative border with Slantsevskiy district;

from the west ‐ along the state border of the Russian Federation and Estonia.

Geographical location defines a special position of the Kingiseppskiy district in Leningrad region.

Almost half of the administrative boundaries of Kingiseppskiy district coincides with the state border of the Russian Federation. The District borders with two countries of the European Union ‐ Estonia and Finland. The border with Finland is exclusively marine. Kingiseppskiy District has the largest water area of the Gulf of Finland in comparison with the others districts of Leningrad region. The district also includes islands located there in. The largest of them ‐ Hogland, Greater and Lesser Tuters, Powerful (Lavensaari), Seskar and Small (Penisaari).

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The coastline is about 126 km. It runs along the Gulf of Narva, Koporskaya Bay and Luga Bay. Luga Bay is suitable for navigation of large ships. This part of the Gulf of Finland has a short period of freeze‐up and the depth is suitable for navigation that allows constructing large‐scale modern seaport. Within the area there are lower reaches of two navigable rivers ‐ Narva and Luga, those are connected with each other by another navigable river ‐Rosson.

The district is a frontier area and important highways of federal importance (namely roads and railways) cross the territory. Federal highway "St. Petersburg‐Tallinn" goes though Kingisepp town.

Total area of Kingiseppskiy municipal district is 290 800.00 hectares. Municipality "Kingiseppskiy municipal district" includes the following settlements: Kingiseppskoe, Ivangorodskoe, Bolshelutskoe, Vistinskoe, Kotelskoe, Opol’evskoe, Nezhnovskoe, Pustomerzhskoe, Ustlugskoe, Falileevskoe. The total population is 81 700 people (4.5% of the total population of the Leningrad region).

Geographical location of the district contributes to its social‐economic development. Economic condition of the district is at a high level and is one of the main in the region. The district has a wide profile of industrial orientation and is based on its own natural resources and has a high economic potential. Economic development of the district is above the average of the region. There is well‐developed network of regional roads, those connect almost all settlements with central roads. Great influence on the development of the district has the construction of Ust‐Luga seaport.

1.2 Territory land tenure and condition of general plans Vistino rural settlement is located on a peninsula along Sojkinskaja Luga Bay of the Gulf of Finland. The northernmost point of the peninsula Soikinsky is cape Kolgomlya. In the central part of the territory there is Sojkinskaja hill, maximum depth is about 136 meters above the sea level. About 60% of the land is covered by forests, mostly coniferous.

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1.3 Objects of natural and cultural heritage and protected areas Table 1. Description of protected areas

Name of area Description

State natural complex sanctuary «Oakwood near Velkota Village»

The sanctuary is regional. Located in the vicinity of the Velkota village and in blocks 89 and 115 of Kotelsky forest area of Kingiseppskiy forestry. The area of the sanctuary is 375 hectares.

State regional nature complex sanctuary "Kurgalskiy"

State nature complex sanctuary is located on the Kurgalskiy Peninsula. Area of the reserve is 59,950 hectares (area of the peninsula and the islands is 20 702 hectares, 848 hectares of water area of lakes and 38,400 hectares ‐ water area of the Gulf of Finland).

Wetlands "The Kurgala peninsula"

Wetland "The Kurgala peninsula" have the international value and was created for purposes of compliance of Russia with obligations those are following from the Convention on the Wetlands, having the international value mainly as habitats of waterfowl, and recommendations of the Parties of this Convention.

State integrated nature wildlife sanctuary

“Kotelsky”

The wildlife sanctuary "Kotelsky" is organized on the basis of Lenoblispolkom's decision in 1976. The area is 10690 hectares, where the water area of lakes is 3000 hectares.

Natural complex area “Soykinsky coast”

The territory supposed to be a sanctuary is on a northwest extremity of the Soykinsky peninsula.

Hydrological natural area “Rosson river valley”

The territory supposed to be a sanctuary is the river Rosson connecting deltas of the Luga river and Narva river. The area is unique on the hydrological regime. Rosson connects Narva river with the Luga River that flows in 15 km to the East.

Suggestions to organize of the ethno‐cultural reserve in the area of the Luzhitsy

village

Ethnographic capacity of the Kingisepp municipal area is defined by accommodation on its territories of the people of different cultures – the Russians, the Vod, the Izhorians, Finns‐Ingermanlands

The Izhora ethnographic museum in Vistino village

The ethnographic museum located on Tsentralnaya Street, in the village of the Vistino of Kingisepp region of the Leningrad region, Izhora plays one of leading and significant roles in the course of preservation of original cultural values of the Finno‐Ugric people under the name of Izhor.

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2. HYDROGRAPHY The territory of the municipal area has the developed hydrographic network belonging to the basin of the Baltic Sea, presented by the Luga and Koporsky Bays of Gulf of Finland of the Baltic Sea, the rivers and lakes. Regarding nourishing conditions the hydrographic network of the territory belongs to the East European type with the maximum spring snow high water and the small autumn rain. Seasonal distribution of a drain is uneven and more than 40% happens in April‐May. In winter the nourishment of streams and lakes mainly happens at the expense of underground waters that promoted by proximity of glint, delineating the Ordovician plateau formed by karst limestone and dolomite.

2.1. Resources of underground waters

Figure 3. typical lithological section area near the Vistino

Within the Kingisepp area 6 water‐bearing complexes and formations are widespread. By results of calculations of expected operational stocks of underground waters for the water‐bearing formations, executed by PMA "Sevzapgeologiya", stocks for the Kingisepp area are the following:

• expected reserves of fresh waters of the Lomonosov water‐bearing formation within the lowland are equal 4 thousand m3/d; • expected reserves of fresh waters of the Lomonosov formation, Cambrian and ordovician complexes are equal 460 thousand m3/d.

The existing water intake does not exceed 10% of perspective stocks. However nature of distribution of resources of fresh underground waters and specifics of hydrogeologic conditions of certain territories of the area does not allow counting on full on drinking water supply of the area with underground waters near consumers. So, the northern part of the area, including the Vistino settlement, is not provided with fresh underground waters which by quantity and quality could be a source of the centralized water supply. The Lomonosov water‐bearing forming emerges under quaternary deposits in northern part of the area. Underground waters are pressure head, pore‐deposit. Fresh waters with a mineralization 0,2‐0,6 g/dm3 are widespread in places of exits of the formation under quaternary deposits. In process of immersion the mineralization increases to 2, 5 g/dm3. The centralized water well‐field is not made; operation is conducted by single wells. Most surface waters that are relatively easy get, can have radioactive contamination.

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2.2. Resources of surface waters Belaya river is used as a source of drinking water for Vistino village. Belaya river belongs to the basin of Habolovka river and refers to the 3rdclass of Division B in accordance with the classification of water objects according to GOST 17.1.1.02‐77. Belaya river flows from wetlands of coast Luga Bay, located five kilometers from the coastline of the Gulf of Luga Bay. Soils in the catchment area are boulder loam, sandy loam, sand with gravel and pebbles, underlained by Silurian karst limestone. Valley slopes are from medium steep to very steep. Their height increases downstream from 1.0‐1.5 m to 6.8 m.

In hydrological matter Belaya rivers an unexplored river. Characteristics of minimum flow is obtained by estimated calculation. According to the certificate SU "St. Petersburg CGMS‐R" minimum estimated natural 30‐day water consumption is 95% of Belaya river supply during the period of summer‐autumn base flow is 0,020 m3/sec. During the winter base flow water consumption is close to the summer‐autumn values.

Spring flood at Belayariver, by analogy with the small rivers of this region, usually begins in late March ‐ early April. The average duration of the flood is 15‐20 days. Flood peak is in the mid of the April. Water raise level of average spring flood above the average winter base flow is 0.6‐0.7m. Spring flood recession lasts about 45‐50 days. Usually the end of the flood starts in early June.

Water protection zone width is 50 m.

Riverside protection zone is set based on the slope of the shore of the water object and is 30 m for reverse or zero bias, 40 m for slopes up to three degrees and 50 m for the slope of three or more degrees.

The strip of land along the shoreline of the water object for public usage (the riverside) is 5 m. Table 2. Laboratory water test, Belaya river, 1st stage, WTP

Pos. number Ingredient name Measuring unit 16.12.2013 26.02.2014

1. Odor score 0 0

2. Color grad 126.6 130

3. Turbidity mg/dm3by kaolin 0.85 0.8

4. РН 6.3 6

5. Oxidability 18.24 16.32

6. Rigidity 1.25 2.3

7. Dry sendiment mg/dm3 68 86

8. Anionic surfactant mg/dm3 0.015 0.015

9. Oil products mg/dm3 0.05 0.05

10. Phenol (total and volatile) 0.0005 0.0005

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Lakes

Within the boundaries of the municipal area there are located 11 lakes. The largest of them are: Kopanskoe, Glubokoe, Lipovskoe, White, Babinskoe, Habolovskoe. Kopanskoe and Glubokoe lakes are on border with MF territory "Vistino joint venture". The Kopanskoelake has length of 7 km. Water of lakes is low‐mineralized, of a hydrocarbonate class. The general mineralization of water is low and in Babinskoe lakes it is 41.3 mg/l, Habolovo ‐40.8 mg/l, Sudachye ‐ 37.1 mg/l.

Table 3. Monitoring of water area of water object in 2013 year.

Position

number

Param

eter

to control

Measuring

unit

April

May

June

July

August

September

October

MPC of fish

pond

1. рН ед. рН 8,12 8,18 8,18 7,7 8,01 7,72 7,68 8,5

2. Dissolved oxygen mg О2/dm3 14,3 16,6 15,24 11,54 9,6 11,11 10,41

3. Suspended solids mg/dm3 ≤3 ≤3 9,1 ≤3 4,8 11,2 ≤3 сф+0,25

4. BOD5 mg/dm3 0,85 ≤0,5 2,84 0,1 ≤0,5 0,92 ≤0,5 2

5. COD bichromate mg/dm3 50 60 54 31 20 17 19 15

6. Phenols mg/dm3 0,002 0,003 ≤0,0005 0,003 0,002 0,004 0,003 0,001

7. Sulfates mg/dm3 64 71 64 92 64 46 37 100

8. Chlorides mg/dm3 670 690 690 86 2300 2350 535 300

9. Phosphorustotal mg/dm3 ≤0,02 ≤0,02 ≤0,02 0,023 ≤0,02 0,026 0,025

10. Nitrites mg/dm3 ≤0,01 ≤0,01 ≤0,01 ≤0,01 ≤0,01 ≤0,01 ≤0,01 0,08

11. Nitrates mg/dm3 0,01 ≤0,01 ≤0,01 0,01 ≤0,01 0,04 0,04 40

12. Ammoniumnitrogen mg/dm3 0,12 0,12 0,067 0,064 0,057 0,021 ≤0,02 0,5

13. Nitrogen total mg/dm3 ≤1 ≤1 ≤1 0,38 0,63 0,446 0,39

14. Petroleum hydrocarbons mg/dm3 0,05 0,04 0,05 0,03 0,13 0,03 0,04 0,05

15. Iron mg/dm3 0,04 0,05 0,12 0,07 0,06 0,27 0,05 0,1

16. Copper mg/dm3 0,002 0,002 0,0023 0,001 0,011 0,0074 0,001 0,01

17. Manganese mg/dm3 0,017 0,015 0,004 0,015 0,008 0,04 0,07 0,01

18. Zinc mg/dm3 0,005 0,002 0,009 0,012 0,013 0,011 0,004 0,01

19. Nickel mg/dm3 0,005 0,003 0,005 ≤0,002 ≤0,002 0,0041 0,006 0,01

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3. DESCRIPTION OF EXISTING WATER SUPPLY AND SEWAGE SYSTEMS OF “VISTINO RURAL SETTLEMENT”

3.1. Main information about Vistino

Figure 5. Population dynamic

Table 4. Population of Vistino rural settlement

Municipality Locality Distance from administrative

center, km Population, inhabitants

Vistino rural settlement Vistino village Valyanitsi village Glinki village Gorki village Dubki village Zalesie village Koskolovo village Koshkino village Krasnaya Gorka village Logi village Logi community Mishino village Novoe Garkolovo village Pahomovka village Ruch’I village Slobodka village Smenkovo village Staroe Garkolovo village Yugantovo village

Administrative center

1,5 4,5 3,5 4 3 15 7 5 4,5 6 7,5 16 2 2 8 4,5 19 6,5

Total ‐1901 991 51 55 113 17 45 9 3 10 92 14 20 5 40 319 35 3 15 64

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Table 5. Characteristics of the housing.

Municipality

Volume of the housing, thousand of m2 of total area

Total including

Apartment building Individual houses

Vistino rural settlement 74.9 10.1 64.8

Table 6. demographic forecast

Settlement 1990 1997 2007 2010 2014 2020 2030

Vistino 897 907 991 821 995 2890 4356

In the villages there is the process of replacement of wooden houses for stone fundamental houses. Level of engineering accomplishment in villages is very low.

Table 7. Engineering level of housing

Municipality Percentage of engineering equipment provision of the housing (%)

Water supply

Sewage Central heating

Baths Gas Hot water supply

Telephones

Vistino 25 20 30 12 0 0 4

3.2. General characteristics of water supply and wastewater systems

Currently, the territory of the settlement, except village Vistino, has no central water supply and sewage systems. History of construction of a centralized water supply and sewage systems at Vistino.

Table 8. Stages construction

Year Stage

1936 Construction of water intake, water treatment plant and water distribution networks

1982‐1989 Reconstruction of water intake and construction of sewage treatment plant, gravity flow collector, treated water distribution networks and sewage system for water tower (currently out of use), step up pumping stations

2008‐2012 Construction of networks to base "Efesk" and hotel "NOVOTEK". Compound of village houses for water supply purposes have on their individual plots dug wells to a depth of 8 meters.

Main water supply for Vistino village is organized from surface water source – Belaya river. Water purification is performed on water intake treatment plants (WTP) "Belaya Rechka". The capacity of plant is 400 m3/day. Structure of facilities and their technical condition will be indicted hereinafter. Wastewater from consumers of Vistino village via gravity sewer collector flow to biological treatment plant of project capacity 1670 m3/day and after treatment and disinfection is discharged into the Luga Bay of Gulf of Finland of the Baltic sea. The sewage system is in very bad condition, which entails environmental degradation and violate water protection zones of rivers and their tributaries. Other localities of the settlement do not have a centralized pumping domestic sewage. Inhabitants enjoy raking or outhouse toilets, which don’t have appropriate degree of waterproofing, that leads to pollution of aquifers. In very rare cases, on the private plots bio toilets are installed. Now days the water supply and sewage objects are of municipality property of the settlement and are exploited by the "Sevzapkommunservis" company under the lease agreement.

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3.2.1. Characteristics of the water supply network The total length of the centralized water supply system networks in Vistino settlement is about 13.5 km. 1.8 km out of these is needed replacing.

Table 9. Sewage and Water supply network

Network segment Material Ø mm length km

Sewage water network

From water intake and treatment facilities "Belaya rechka" to Vistino village

cast iron 350 9.6

To the water main pipe connected) that supply water to JSC "Novatek" PND pipe 200 3.6

Water supply network

Distribution networks cast iron 150 515

100 380

50 84

steel pipes 150 292

100 1993

50 719

32 24

At the same water pipe in the area of Smenkovo village there is intermediate concrete treated water tank (TWT) of 500 m3 volume (CWT). Due to significant changes in elevation 2 step up pumping stations were constructed in Vistino village. First step up pumping station does not operate because there is no necessity as after TWT water comes to the village with a pressure of 3.0 kg/cm2). At the second step up pumping station pump K 20/30 brand (1 pc.) with frequency converter is installed. Installation of frequency converter provides energy saving. SPS number 2 delivers water to the upper part of the village to the three‐stored houses.

3.2.2. Characteristics of the sewage network Sewer network length is about 5.5 km (1 mile ‐ collector Ø 250 mm; 4.5 km ‐ internal networks), a discharge from WTP ‐ 600 m, Ø 250 mm, pipe material: cast iron, ceramics. 176 sewage wells are constructed on the networks. 95% of the networks and their facilities have been built during the 1982‐1989 years. The networks are pretty worn. Below the route of water supply and sewage networks are shown.

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Figure 4. Water supply and sewage networks of Vistino village.

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3.2.3. Water consumption volume and wastewater volume Table 10. Physical indicators of water supply

Parameter Measuring

unit Fact 2013

Plan 2014 Comment

Total volume of water intake 1000 m3 57,6 72,1

Own needs 1000 m3 5,8 7,1 10%

Total volume to distribution network 1000 m3 51,8 65

Leakages 1000 m3 31% 25%

Total volume of water distributed from water supply network , including:

1000 m3 46,7 55,5

Population 1000 m3 15,7 19,9

Budget consumers

1000 m3 2,9 3,0

- Water supply companies 1000 m3

- Other consumers 1000 m3 28,1 32,6

JSC «Novatek», 7 months during 2013 year

Total consumption of power, including:

1000 kW h 152,4 167,5

- Power consumption for technology needs

1000 kW h 125,5 140,5 Frequency converter is installed at SPS

- Specific energy consumption for technological needs

kW h /m3 2,18 1,95

Characteristics of WWTP: start of construction of wastewater treatment plants (WWTP) ‐ 1982, commissioning ‐ 1989. CBS p.Vistino built on the Model T‐1646 project (artist: TSNIIEP Engineering equipment). CBS intended for cleaning households. domestic wastewater and sewage p.Vistino from fish farm "Baltika". Design capacity of 1670 m3/day structures., actual ‐ 42.8 thousand m3/year, 118 m3/day. (in fact in 2013.). How they calculate water losses. Metering of distributed water is organized by metering devices. Own (technology) needs and the volume of leakages is within the limits. The growth of the leakage volume is caused by wear of the distribution pipes. Every year the volume of water intake is growing, for example in 2010 water intake was 34.4 1000 m3 per year, in 2013 ‐ 57,6 1000 m3 per year. Increase of water intake was due to the growth of water sold to the needs of the population (labor inflows to build port facilities) and water use for construction enterprises. Table 11. Forecast of water consumption Vistino

Water supply 2014 2020 2030

m3/year 63200 172800 357000

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A strong increase in water consumption due to the development of port infrastructure "Ust‐Luga" Table 12. Calculation of consumption of water supply services by population in 2014 year

Position number

Accomplishment type Consumption norm, m3/people/month

Number of consumers, people

Year consumption, 1000 m3

Vistino village

1

Full accomplishment

with installed metering devices

2,37 611 17,377

without installed metering devices

5,47 14 0,919

2

Houses with/without baths, with water supply and sewage


2,27 22 0,599


3,95 19 0,901

3

Houses with water supply and without sewage


1,18 11 0,156


3,04 0,000

Total for population 677 19,951

Table 13. Sewage indexes of Vistino village

Index Measuring

unit Fact 2013 Plan 2014 Comments

Total volume of waste water, including: 1000 m3 42,8 46,8

Industrial discharge – total, including:

34,5 41,2

- Population 1000 m3 15,7 19,9

- Budget consumers 1000 m3 2,9 3,0

- Other consumers 1000 m3 15,9 18,3

Infiltration 1000 m3 5,6 5,6

Total volume of treated waste water, including:

1000 m3 42,8 46,8

For full biological treatment 1000 m3 42,8 46,8

Total consumption of power, including: 1000 kW h 140,8 148,5

- Power consumption for technology needs

1000 kW h 82,6 90,3

- Specific energy consumption for technological needs

1000 kW h/m3

1,93 1,93

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Table 14. Forecast of waste water consumption Vistino

WWater 2014 2020 2030

m3/day 120 320 650

3.2.4. Calculation of infiltration

Table 15. Calculation of weighted rate for the sewage warm season.

№ surface Area flows F, hectare

Runoff coefficient, W

F*W

1 Area with a paved 2,8 0,6 1,68

2 lawns 49 0,1 4,9

in total 51,8 6,58

C. average.= 6,58/51,8 = 0,125

Calculation of the volume of surface runoff for the year.

According hydrometeorological station "OGMS Kingissepp" total amount of precipitation in the 12 months 2013. was ‐ 624.1 mm.

Table 16. Amount of precipitation

month amount of precipitation (mm)

January 42.1

February 28, 2

March 5.5

April 36.0

May 69.8

June 60.2

July 44.7

August‐ 51.7

September 60.2

October 54.9

November 63.8

December 44.8

Table 16. Calculation of weighted

№ Flow The layer of the precipitate, h mm.

S ha Кu Кav V

т.м3/year.

1 Rain 386,87 51,8 0,125 25,0

2 Thawed 157,23 51,8 0,6 0,65 31,4

Total 544,1 56,4

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Formulas for calculation:

Vд=10*h*S*kср.

Vт=10*h*S*ku*Kav., где

Ku factor as used in the case of snow removal from the territory

The average annual volume of infiltration of rainwater and meltwater Wk.inf cube. m entering the sewage system of the village on the square S, ha determined by the formula

Wk.inf = k2 * V,

where k2 ‐ dimensionless coefficient accounting for infringement of tightness butt

compounds of sewer pipes, coupling pipes locations with wells and components wells received 0.1 to 0.5 depending on the sewer system.

Wk.inf = 0.1 * 56.4 = 5.64 t.m3/year

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3.2.5. Balance of water supply and sewage systems

Figure 5. Water Balance

Water reservoir on the Belaya River

WTP «Belaya River» Q= 197,5 м3 /сут.

Served to the pumping station of the 2nd ascent. Q=197,5м3/сут.

washing filters. Q=19,7 м3/сут. ( 10%)

Belaya River

Total Filed in the city's network. Q= 177,8м3/сут

d.Vistino Q= 62,5м3/сут (41,2 %)

OAO "Novatek" Q= 89,2м3/сут. (58,8 %)

Network losses Q= 26,1 м3/сут. ( 14,7%)

Drains from inhabitants Q=112,9 м3/сут

Conceded by WWTP Q=128,2.м3/сут.

infiltrate Q=15,3.м3/сут

Luga Bay Gulf Baltic Sea

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3.2.6. Water intake and treatment facilities Water intake and water treatment facilities at Vistino village have been constructed in accordance with typical design project TP №3‐901‐80 in 1987‐1988. Water source is Belaya river that is a small river of the 1st class. River feed is mainly ground‐snow. Flood periods ‐ spring and autumn, although if there are a lot of rains during summer period the water level can go up as well. Taking into account the low water level of the rivet at the water intake, a piled up dam have been constructed with concrete culvert devices.

Figure 6. Dam WTP

Figure 7. Struya‐800

The volume of the water reservoir stable provides water intake treatment facilities "Struya‐800" at any time during the year. Currently water source water is high colored, low turbidity, with low alkaline reserve, high rigidity and pH. High color water of water source, requires a high raw water chemical treatment using a coagulant and soda.

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3.2.7. Existing water supply and water treatment process

Water from gabion via deepened pipes goes to 2 water intake wells, those are connected to the 1st stage pumping station. Two pumps type ЭК‐9 (К‐45/90) pump raw water from the 1st stage pumping station via pipes 250 mm diameter to с treatment facilities.

Figure 8. 1 stage pumping station

Inside the 1st stage pumping station in 2013 year piping of the pumping equipment was replaced for polyethylene pipes and water metering unit was installed with metering device VSKHN‐150. The accuracy of meter data are doubtful, as usually the metering device to be installed should be about 1‐2 caliber smaller than the diameter of the main pipe. Today the metering device VSKHN‐150 is installed on the polyethylene pipe with diameter of 160mm. The 1st stage pumping station is equipped by workshop for preparation of soda solution that is dosed into the suction pipe of the inlet well. The gap between dosing soda and coagulant is about 2 minutes. Coagulant solution in the required doses, is being dosed into the pressure pipe connector assembly of 2 units before the flocculation chamber. Disinfection reagent ‐ a solution of sodium hypochlorite ‐ is being dosed into the filtered water. Before the flocculation camera there are sieve filters to trap big floating impurities. Treatment facilities “Struya‐800” configured of two typical treatment units “Struya‐400” with total capacity 800 m3 per 24 hours. This treatment unit consists of:

grid filter

flocculation chamber, совмещенная с трубчатым отстойником

sand pressure filter

equipment for coagulation, chlorination and water stabilization.

23

Figure 9. Water intake and treatment facilities, equipment “Struya‐400”

After that water flows into the flocculation chamber where after the coagulant have been dosed flakes of aluminum hydroxide form with the extraction from water of suspended and colloidal particulates. The resulting flakes arrive into the chamber with drums consisting of filled tubes DN 40‐100 mm, arranged at an angle of 60о. Intensive water clarification is achieved by sedimentation of particulates in the tubes of the отстойника. Simultaneously there is a mixing of the part of the sludge in the flocculation chamber. Distilled water with a bit of turbidity is being sent to sand filters for the final cleaning. After that water flows to the treated water tank where pumps of the 2nd stage pump it to the distribution pipe and then to the consumers via main pipeline (length 14 km). Filters are filled with quartz sand of a certain fraction. In accordance with the technical regulations filters are to be washed. As a result of filters washing there are rinsing waters those are to be discharged through coastal discharge, which is a steel pipe DN 250 mm and a length of 100 m located on the right bank of the Belaya river. The discharge is located at a distance of 10 m from the water, the place of discharge is fortified by granite natural stone at a distance of 0.5 m up and downstream of the discharge. Elements of the facilities:

sedimentation: pipes, diameter – 2 m, quantity – 2 pcs.

pressure filter: sand, diameter – 2 m, quantity – 2 pcs.

sieve filter– 2 pcs. Dosing of coagulant and hypochlorite is organized by dosing pumps D‐VA‐98‐10, capacity 98 l/h, engine power 0.25 kW. Dosing of soda is used pump D‐VA 135/10, capacity 135 l/h, engine power 0.25 kW. Chlorination. Elektrolitny unit EN‐25, 2 pcs, one is operating and the other one is standing by. The unit consists of: solution tank– 1 pcs, electrolyzer – 1 pcs., operational tank – 1 pcs, rectifier – 1 pcs, dosing pump GND‐25/25 – 1 pcs.

24

Figure 10. Electrolysis room.

In the 2nd stage pumping station the following pumps are installed: 1. NM 50/20 B/B ‐ 3pcs., (Q=24‐78 m3/h, H=23‐48 m; N=9,2 kW); 2. Wash pump RB‐200, (Q=200 m3/h, H=20m, N=22 kW)

On the territory of the water intake and treatment plant there is a clean water reservoir‐1pcs.,Q‐50m3. The 2nd stage pumping station via cast iron pipe of diameter 350 mm pumps water to Vistino village. On the territory of water intake and treatment plant a diesel generator type A‐01ME is installed that is used when there is no electric power supply. Technological process at the station is controlled by laboratory that is located at the territory of the water intake and treatment plant "Belaya Rechka". Besides monthly water quality monitoring is done by Center of Hygiene and Epidemiology in the Leningrad region in Kingiseppskiy district. Quality of drinking water purification needs improvement. Taking into account the forecast population growth, increase water treatment plants providing capacity with 2 lines. Cleaning quality does not satisfy residents. This is due to outdated equipment and a high degree of wear of water networks.

3.2.8. Proposals for a water purification system

As a purification of water supplied to habitants, a system based on the principles of microfiltration. Estimated composition of water treatment plants:

‐ Block profiteered water. Automatic mechanical filtration with crevice 200. At the heart of the filtering elements of the cartridge is compressed polypropylene discs micro channels are in a compressed state to form a filter element. The advantage of these elements is that the elements are little subject to wear. When pollution wheels pushes the washed, completely restoring their filtering ability.

‐ Chemical dosing unit Node proportional dosing ‐ is designed for input to correct reagent salt in water, to ensure efficiency ultrafiltration system. The metering unit with built‐in pH meter. Is used to adjust the pH.

‐ Block the main water purification from organic substances

25

Ultrafiltration unit. The unit is designed for cleaning water from surface sources from mechanical impurities, suspended solids, organic compounds and bacteria. The principle of operation of the plant: Source water is treated by coagulation and then passes on the ultrafiltration membrane cleaning. Due to the fact that the pore size of ultrafiltration membranes is very small , then the process of coagulation sufficient 30 ‐ 60 seconds of residence time , so the coagulant is dosed directly into the raw water supply pipe in an amount much smaller than in a classical water treatment scheme . Purified water is collected into purified water storage container. Minority (about 5‐15 %) is used for backwashing the membrane, and most of the served user. The choice of this water purification technology a number of reasons, first of all ‐ the poor quality of drinking water in urban areas associated with disabilities of existing treatment facilities. Sandy granular filters that are part of all water treatment plants, are often unable to hold very small particles (colloids) , bacteria and viruses , usually developing in these filters . It is through ultrafiltration membranes can be cleaned with water to European quality standards, because these membranes have a pore size of 0.002 ‐ 0.1 microns, allowing delay bacteria and viruses. Also note the simplicity of installation of such systems, namely, each such conduit system is connected to a source of water, the purified water pipe (for pure water storage tanks), a conduit supplying the washing water from the clean water tanks and the sewer pipe. System storage tanks with the automation system ‐ a prerequisite of ultrafiltration unit, is required to create the volume of purified water for hydraulic and chemical cleaning ultrafiltration unit. The material from which made storage tanks ‐ plastic, making them easier to transport and ensures the longevity of their service life. The system is protected against tanks overflow and automation fill them.

‐ Block secondary water purification from residual organics Rising pumping station based on low noise pumps Grundfos. In this pumping station consists of 3 pumps (2 working and 1 standby). System Automation station pumps work alternately switches , thereby achieving uniform load on pump motors in the station . All pumps are equipped with a frequency converter station, providing soft start equipment and lack of water hammer in the system. Also a complete pumping station includes an accumulator 500 liters. to reduce the number of on / off pump motor and system protection startup pump "dry ." Water enters the system at a continuous carbon filters intended for cleaning water to the residual chlorine, tastes, odors and organic compounds. Loading filter ‐ activated carbon produced from special grades of bituminous coal, characterized by a narrow particle size distribution, has a high activity. Activated carbon is characterized by a selective pore structure, which provides a high degree of absorption and the ability to impregnate. Also, are sufficiently resistant to abrasion, to resist the repeated regeneration. Mode of operation: Water is passed through the column at a time. Process is controlled by an electronic control unit, according to testimony which the controller determines the need for regeneration of a particular column. Controller independently carries regeneration column , this time providing the consumer with purified water from other columns. Regeneration of the filter automatically reverse current of water.

‐ Block water disinfection The metering unit is in automatic mode. If necessary, one can easily change the dose of the reagent.

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3.2.9. Waste water treatment facilities Wastewater discharge of Vistino village is organized through sewage treatment plant’s discharge into the Luga Bay of the Gulf of Finland. Sewage network of Vistino village is separate. Civil sewage from the village and recreation via gravity collector of total length 5493 linear meters and diameter 250 mm is going to the intake department of waste water pumping station at Sewage treatment facilities (pipe material: cast iron and ceramics). Start of construction of wastewater treatment plants (WWTP) ‐ 1982 year, commissioning – 1989 year. WWPT of Vistino village are built in accordance with typical design project T‐1646 (contractor: “Engineering equipment” company). WWTP have been built to treat civil sewage and intended for cleaning households. domestic wastewater village Vistino and sewage from fish collective farm “Baltica”. Designing capacity of the WWTP is 1670 m3 per day, fact – 42.8 1000 m3 per year, 118 m3 per day (fact, in 2013 year). Structure of WWTP:

Administrative building

Waste water pumping station

Figure 11. Waste water pumping station.

Figure 12, 12A. Tank block aerotank‐clarifier – 3 pcs.

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Figure 13. Post precipitation.

Figure 14. Biological ponds – 2 pcs.

28

Figure 15. UV disinfection unit.

Figure 16. Sludge field.

29

Figure 17. Blowers.

Figure 18. Boiler building.

30

Technological treatment scheme

Wastewater flows into the receiving chamber of the waste water pumping station (capacity 173 m3/h, depth 5.5 meters). For flow measuring of the sewage delivered into the receiving chamber there is a device for proportional discharge. From the receiving chamber sewage is delivered by pumps SM 125‐80‐315/4 (1pc.) and SD 50/56 (2 pcs.) into the aero tank‐clarifier, which consists of two compartments separated by a shield. Dimensions of the tank are 36x6 m (3 pcs). Aero tanks (two compartment) are used for biological wastewater treatment. From aero tanks wastewater go to the secondary clarifiers, where suspended fine particles and activated sludge sediment. In the secondary clarifier (dimensions 36x1,4 m) sludge mixture is sedimenting (runoff + sludge). Biological treatment is performed in the extended aeration mode. Aeration in the aeration tanks is pneumatic. Aerators are perforated pipes. Air is forced by blowers located in the separate building (blowers station). Sedimentation zone is equipped by thin‐layer modules. Return of the circulating sludge in the aeration zone is provided by of airlifts. Air for the airlifts is forced by gas blower 2AF51752 (2pcs.) and 1A24302a (2 pcs.), those are installed in the auxiliary building. From the sedimentation zone water flows by gravity through the steel pipes (diameter 200 mm) to biological ponds (2 pcs.). In biological ponds there is further treatment of biologically treated waste water by oxygen saturation. After biological ponds wastewater flow to disinfection by UV unit with lamps DB 15M and DB 30M. Furthermore wastewater is discharged by gravity collector (DN 250mm, length 600m) through the scattering of channel output into the Luga Bay of the Gulf of Finland. Discharge zone is 140 meters from the water's edge. Runoffs from fish farm “Baltica” (now the farm does not operate) come via separate sewer system into the aeration tanks of the waste water treatment plant. Today the situation at WWTP has worsened due to reduction of runoffs volume and pollution load that was caused by the shutdown of the fish farm and the lack of industrial runoffs as a consequence. Besides all the metal facilities have great physical deterioration. Monitoring of the quality of treatment is done by Center of Hygiene and Epidemiology in the Leningrad region in Kingiseppskiy area. Laboratory tests are performed quarterly. Below you can find the results of laboratory examination of wastewater from WWTP of Vistino village.

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Table 17. The results of laboratory examination of incoming and treated wastewater at WWTP of Vistino village.

Parameter name Actual concentration rate, mg/l

Before treatment After treatment Treatment level, %

рН 7 7,7

Suspended solids 461 127 72,45

BOD total 83,5 45,6 45,39

COD 264 96 63,64

Nitrogen total 9,12 11,25

Ammonium nitrogen 10 14,1

Nitrogen nitrate (NO2) 4,9 4,5 8,16

Nitrite nitrogen (NO3) 0,08 0,1

Phosphorus total 1,53 2,61

Chloride 70 120

Iron total 1,34 1,52

Oil products 0,05 0,05

Dry sediment 237 397

Surfactants 0,107 0,068 36,45

Sulfate 25 24 4,00

Phosphate‐ion 4,1 7,4

Manganese 0,05 0,05

Phenol 0,0005 0,0005

Copper

Zinc

Wastewater from JSC "Novatek" is brought to existing WWTP at Vistino village by special transport. During the construction period wastewater is being collected into the waterproof containers ‐ collectors. Technical condition of WWTP of Vistino village is indicated in the following table.

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Table 18. Technical condition of WWTP of Vistino village.

Pos. #

Name of facility Description of

building, facility, equipment

Technical condition

Necessary repair

Result

Necessary finance, 1000 rub.

1 2 3 4 5 6 7

1 Waste water pumps

SМ 125‐80‐315/4 ‐1 pcs.

SD 50/56‐2 pcs.

One in operation, one is standing by, one is in repair

2 Aeration tanks ‐ clarifiers ‐ 3 pcs.

Size:20,8х5,9х4 Rectangular

deepened facility (all out of metal).

One section of aeration tank was prees out by water. 100% deterioration of

metal constructions

Repair of metal construction

and reconstruction

of impermeability

3 Post‐precipitation – 3 pcs.

Dimensions: 4х5,9х4

100% deterioration of

metal constructions

4 UV disinfection Deepened building, self‐made. UV lamps

Just one step and just one lamp in operation

Replace lamps

5

Administrative building with auxiliary industrial building

In limited operational condition

It’s necessary to warm up the building and

make the inside renewal, seal the breaks and

reinforce supporting

constructions of the building.

6 Biological ponds – 2 pcs,

Rectangular deepened facility.

Size of each 24х35 m

In operational condition

Necessary to clean from biological incrustation

7 Sludge field– 6 pcs.

13,5х37,8 m each Out of usage

8 Blowers station

4 blowers (3 in operation. + 1 is standing by)

2АF51752 ‐2 pcs. and 1А24302а‐2pcs.

In operational condition

9 Boiler building Boiler with wood In operational condition

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3.2.10. Suggestions for a waste water treatment system. As the underlying technology accept purification scheme (without agents) and nonchemical sludge treatment provided by fig

Figure 19. Scheme WWTP To implement this scheme used container type modules completely prefabricated: ‐ SNS module , which houses the grille , sewage pumps and measuring unit wastewater flow ; ‐ BTF unit , wet compartment that hosts the primary clarifier ‐ seal , with in‐plane loading aeration ( biotenk ) , secondary clarifier , filter, and dry compartment ‐ all technological and auxiliary equipment (UV ‐ installation, blower , heating and ventilation systems , automated etc.) ; Used modern equipment mechanical dewatering (excess sludge). ‐ All modules have a closed design, insulation, heating and ventilation. , Grit chambers and assembly mechanical dewatering and pumping station sewage effluent flow control assembly and the central ACS placed in a separate production and administrative building (PAZ) . As part of PAZ provides space for staff on duty (there are water and local drainage). Mechanical treatment in the primary settling tank, biological treatment system and after treatment filter , UV ‐ disinfection sewage and sludge treatment in MINERALIZER ‐ compactor is implemented as a part of modular units of container , completely prefabricated . Modular units have local ACS, which receives signals from the central control systems.

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4. FORECASTS OF DEVELOPMENT

4.1 Forecast of development for Vistino settlement. Vistino rural settlements have a special place in the structure of municipal districts and on their development was mainly due to the construction and operation of port facilities and structures. Construction of a large commercial seaport of Ust‐Luga (ICC), as international experience shows, accompanied by coherent industrialization and urbanization neighborhood: are major transportation hubs, combines the capabilities of maritime, rail, road, and in some cases air transport; formation of industrial zones to finalize and partial processing port cargo, as well as other enterprises and residential structures. Vistino village becomes "growth point" territory Vistino rural development in the village, where it is planned placement of production and transportation facilities associated with ICC Calculated spatial planning stages taken in the master plan Vistino rural settlement:

the first stage of the Master Plan ‐ 2025 (the same as the design life "schemes of territorial planning Kingiseppsky Municipal District");

the expected life of the Master Plan ‐ 2035;

perspective, beyond the design life of the project master plan for which to formulate the main directions of urban development.

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4.2 Predicted values of the main indicators Table 19. Main indicators infrastructure Vistino rs.

№ Indicator Unit of measure Сurrent state 2025 2035

1. Territory settlement of all hectare 20299,2 20299,2 20299,2

2. population

2.1. The permanent population ths. 1,9 4,0 17,3

3. The total volume of housing 74,9 175,0 647,6

4. Objects of cultural and of public services

4.1. Objects training and educational purpose

Kindergarden th seats 0,2 0,3 1,0

Teaching Institutions th seats 0,4 0,8 1,9

Ambulance visits per shift 30 80 284

Hospitals beds 3 ‐ 233

Sport clubs th sq.m. 0,1 ‐ 6

Planar structures th.sq.m 0,2 34

Swimming Pools sq.m. water

surface ‐ 130

Club facilities seats 400 ‐ 1384

Movie Theaters seats 0 ‐ 606

Establishment of youth policy sq.m. 0 ‐ 433

Museums facility 1 1 2

5. Engineering infrastructure and landscaping

5.1. water infrastructure

water consumption

‐ Total, including: Th.m3/day 0,12 1,4 5,6

‐ For household needs Th.m3/day 0,05 1,1 4,2

‐ For industrial purposes (except for the cost of water from their own water intakes of industrial enterprises)

Th.m3/day 0,01 0,02 0,03

Water recycling % ‐ 15 20

The average daily water consumption for one person

l. / day per person.

63 280 323,7

including

‐on the household needs l. / day per

person. 26 220 242,8

length of network km 17,0 14,2 31,1

5.2. Wastewater

Total received wastewater

‐ Total, including: Th.m3/day 0,23 1,1 4,4

‐ Domestic wastewater Th.m3/day 0,05 1,0 4,1

‐ Industrial waste water Th.m3/day 0,15 0,15 0,25

Performance of sewage treatment facilities

Th.m3/day 1,67 1,67 4,4

length of network km 5,5 9,2 18,9

5.3. Construction of rainwater drains closed km ‐ 1,87 1,48

5.4. Construction of open drains rainwater km ‐ 0,89 16,97

5.5. Construction of water treatment rainwater

facility ‐ ‐ 2

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5. TECHNICAL SOLUTIONS AND PLANNING SCHEMES 5.1. Drinking water sources

Within this territory provision groundwater is uneven, due to the peculiarities of geological structure and hydrological conditions. The source of water may be used groundwater Ordovician aquifer Izhorskogo plateau. Fresh water, bicarbonate, are widely used for water supply in Kingiseppsky, Volosovsky and Lomonosov district of Leningrad region of. Water intake may be placed on sites or Karstolovo Hrevitsa. Also as an option you can consider the construction of a new water intake and structures‐tions of water treatment on the right bank. Luga outside surges waves of intense action and anthropogenic pollution sources (upper stream village. Mezhniki and Kuzemkino). Regulation of water intake must be specified during engineering surveys. In the village. Logs and pos. Old and New Garkolovo not provide centralized water supply. Sources of water supply in these localities can be underground borehole. Comparison of water supply options for investment shows a significant advantage of the organization of a series of water. Meadows, which can be recommended for further implementation. findings Peak demand costs for municipal water potable plumbing defined to be:

The first phase of the project ‐ 1.1 th.m3/ day.,

Full capacity‐ 4.2 th.m3 / day. Cover these costs is provided by the projected intake of the Luga River. water supply scheme The project envisages the further development of the centralized water supply system Vistino rural settlement. The project envisages the closure of surface water intake on the river. White on primarily due to the increase in population in the territory of Vistino rural settlement increases the need for water. Increasing the capacity of water diversion on. White is not possible, since p. White aridity. Water Vistino rural settlement at first planned to be on the surface of the source p. Meadows near the village of Bol. Kuzemkino capacity of 75 th cubic meters. / Day, to be built for the city of Ust‐Luga. The planned scheme provides for the supply of water to the needs of domestic water, fire and water production and th. The future is possible for domestic water supply use the groundwater Ordovician aquifer Izhorskogo plateau. Water supply scheme Vistino rural settlement as follows: Water from the river Luga will be supplied a pumping station on the first lift intake treatment facilities. Coming cleaning cycle of clean water reservoirs, water will be the second lift pumping station in the network diluting Vistino rural settlement. Water supply for the industrial zone is planned to construct a separate water main. Water supply network on the territory of the settlement is traced in a ring configuration, equipped with armature and fire hydrants. Water recreation, transportation, recreational, agricultural areas is planned to carry out the nearby centralized water supply systems, in the case of the absence of those ‐ from underground water sources from the activities on the preparation of hydrogen.

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Figure 20. Perspective water balance – 2035

38

5.2 Suggestions for water supply system As a purification of water conveyed to the users, a system based on the principles of microfiltration. Estimated composition of water treatment plants:

‐ Block pre‐filter water. Automatic mechanical filtration with crevice 200. At the heart of the filtering elements of the cartridge is compressed polypropylene discs micro‐channels are in a compressed state to form a filter element. The advantage of these elements is that the elements are little subject to wear. When pollution wheels pushes the washed, completely restoring their filtering ability.

‐ Chemical dosing unit Node proportional dosing ‐ is designed for input to correct reagent salt in water, to ensure efficiency ultrafiltration system. The metering unit with built‐in pH meter. Is used to adjust the pH.

‐ Block the main water purification from organic substances Ultrafiltration unit. The unit is designed for cleaning water from surface sources from mechanical impurities, suspended solids, organic compounds and bacteria. The principle of operation of the plant: Source water is treated by coagulation and then passes on the ultrafiltration membrane cleaning. Due to the fact that the pore size of ultrafiltration membranes is very small, then the process of coagulation sufficient 30 ‐ 60 seconds of residence time, so the coagulant is dosed directly into the raw water supply pipe in an amount much smaller than in a classical water treatment scheme. Purified water is collected into purified water storage container. Minority (about 5‐15%) is used for backwashing the membrane, and most of the served user. The choice of this water purification technology a number of reasons, first of all ‐ the poor quality of drinking water in urban areas associated with disabilities of existing treatment facilities. Sandy granular filters that are part of all water treatment plants, are often unable to hold very small particles (colloids), bacteria and viruses, usually developing in these filters. It is by means of ultra filtration membranes may be cleaned water to the European norms of quality, because these membranes have pore sizes from 0.002 ‐ 0.1 micrometers, allowing delay bacteria and viruses. Also note the simplicity of installation of such systems, namely, each such conduit system is connected to a source of water, the purified water pipe (for pure water storage tanks), a conduit supplying the washing water from the clean water tanks and the sewer pipe. System storage tanks with the automation system ‐ a prerequisite of ultrafiltration unit, is required to create the volume of purified water for hydraulic and chemical cleaning ultrafiltration unit. The material from which made storage tanks ‐ plastic, making them easier to transport and ensures the longevity of their service life. The system is protected against tanks overflow and automation fill them.

‐ Block secondary water purification from residual organics Rising pumping station on the basis of low noise pumps Grundfos. In this pumping station consists of 3 pumps (2 working and 1 standby). System Automation station pumps work alternately switches, thereby achieving uniform load on pump motors in the station. All pumps are equipped with a frequency converter station, providing soft start equipment and lack of water hammer in the system. Also a complete pumping station includes a 500 liter accumulator to reduce the number of on / off pump motor and system protection startup pump "dry." Water enters the system at a continuous carbon filters intended for cleaning water to the residual chlorine, tastes, odors and organic compounds. Loading filter ‐ activated carbon produced from special grades of bituminous coal, characterized by a narrow particle size distribution, has a high activity. Activated carbon is characterized by a selective pore structure, which provides a high degree of adsorption and impregnation possibility. Also, are sufficiently resistant to abrasion, to resist the repeated regeneration. Mode of operation: Water is passed through the column at a

39

time. Process is controlled by an electronic control unit, according to testimony which the controller determines the need for regeneration of a particular column. Controller independently carries regeneration column, this time providing the consumer with purified water from other columns. Regeneration of the filter timer automatically at a specified time reverse current of water.

‐ Block water disinfection Hypochlorite metering unit operates automatically. If necessary, one can easily change the dose of the reagent.

5.2 Technical solutions ‐ sewage systems

Table 20. Preliminary calculation of the volume of wastewater

Vistino settlement

Period, year.

population, persons

Consumption norms for 1 person. l /

day

Actual consumption, m3/day

The projected water

consumption, m3/day

Industrial needs 25%

The total volume of wastewater m3/day

Сurrent state 2014 1901 177,8

1st stage 2025 4000 200 800,00 200,00 1000,00

full development

2035 17300 200 3460,00 865,00 4325,00

5.2.1. Technical description and basic parameters of the various options

Development of the area municipality "Vistino rural settlement" provides a major reconstruction of sewage system by implementing one of the proposed options. Option 1: Construction of a new main sewer "Valyanitsy ‐ Yugantovo", whose main objective is to provide the best possible reception of sewage from settlements located in close proximity to the A121 highway, including pos. Valyanitsy, Vistino, Ruchi, Dubki, Smenkovo, Krasnaya gorka, Yugantovo. For villages located at some distance from the main sewer (including settlement. Logi, Glinka, Gorki, Zalesye, Pahomovka, Koshkino, Mishino, Slobodka) provides gravity sewer system within the boundaries of the village, and the device CND (sewage pumping station) in the lower part of the network, as well as the construction of pressure sewer network for supplying the main drains on the gathering "Valyanitsy ‐ Yugantovo"

5.2.2. An assessment of the pipe network in need of refurbishment and recommended method of

reconstruction.

Given that the centralized municipal sewage Municipality, MO "Vistino rural settlement" covers only part of the settlements, does not provide the necessary bandwidth, as well as taking into account the high level of deterioration of existing networks and structures, providing a complete replacement of sewer networks and facilities to the new. This solution will fulfill the necessary requirements for the population with housing and communal services, accelerate the development of territory of the municipality, as well as provide a high level of energy efficiency in the industry. According to preliminary data, the volume of construction will be:

township network

gravity sewer network D = 160mm ‐ 20 km

gravity sewer network D = 200mm ‐ 2.0 km

network pressure sewer D = 90mm ‐ 3.6 km

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main sewer

D = 250mm ‐ 7.6 km

D = 315mm ‐ 4.0 km

D = 400mm ‐ 1.6 km Release from CBS D = 400mm ‐ 1.0 km Pumping Stations

sewage pumping station 270 m3 / h ‐ 1 pc Sewage treatment plants

CBS 4500 m3/day Similarly, Option 2 Option 1 provides for the construction of the new main gravity collector "Valyanitsy ‐ Yugantovo", whose main objective is to ensure reception of domestic wastewater from settlements of the municipality, in this case, in each village organized pressure sewer system «Presskan». The uniqueness of this system is a device for a group of buildings (1 to 10) fiberglass well equipped pump "1 1/4'' NP ‐ 02", specially designed for this system, which due to their characteristics allows to provide stable operation with parallel connection to single standpipe network. System «Presskan» specially designed for sparsely populated settlements located in a hilly area, far away from the endpoint receiving wastewater. This system eliminates the gravity drainage areas, reduce the cost of network construction deep foundations (over 2 meters), and the installation of manholes on the network. The whole system is combined into a common discharge manifold D = 63‐90mm and is tight. Wastewater treatment and discharge into the Luga Bay Gulf of Finland provided similarly to the first embodiment, through the new wastewater treatment plant. The length of pipe diameters, in need of refurbishment. Whenever possible, the recommended method of reconstruction. According to preliminary data, the volume of construction will be:

township network network pressure sewer D = 50mm ‐ 15 km gravity sewer network D = 160mm ‐ 7.0 km Chap. collector

D = 250mm ‐ 7.6 km

D = 315mm ‐ 4.0 km

D = 400mm ‐ 1.6 km Release from CBS D = 400mm ‐ 1.0 km

Pumping Stations sewage pumping station 270 m3 / h ‐ 1 pc Sewage treatment plants WWTP 4500 m3/day

5.2.3. Assessment of the risks and impacts of different options. In comparing the two options presented, in terms of the possible risks of environmental impact, it is preferable to the latter, since most of the networks is a sealed system, without the pressure device manhole that allows to prevent sewage in the soil, thereby increasing the current environmental safety area. Also the second option less investment costs, but you must consider the fact that the equipment used in the construction can not be replaced by similar domestic production, which should certainly be taken into consideration when choosing the final version of drainage area municipality "Vistino rural settlement."

41

5.2.4. Comparison of different options in terms of cost and effect. Option 1

The cost of building networks township 37.2 million rubles.

The cost of construction of the main reservoir of 41.2 million rubles.

Construction cost of manufacture from CBS, including deep waters 60.0 million rubles.

The cost of building CND 20 m3 / h ‐ 5 pcs 15.0 million rubles.

The cost of building CND 270 m3 / h ‐ 1 pc 8.0 million rubles.

The cost of building new CBS 4500 m3/day 200 million rubles.

Total for option‐1363860 000,00 rub. Option 2

The cost of building networks township 33.0 million rubles.

The cost of construction of the main reservoir of 41.2 million rubles.

Construction cost of manufacture from CBS, including deep waters 60.0 million rubles.

The cost of building CND 270 m3 / h ‐ 1 pc 8.0 million rubles.

The cost of building new CBS 4500 m3/day 200 million rubles.

Total for option‐2344660 000,00 rub.

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Figure 20a. Scheme Wastewater infrastructure

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Figure 20b. Scheme Wastewater infrastructure

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6. GUIDELINES

To develop this report, we used the following algorithm: 1) Data collection and filling the questionnaire (questionnaire ‐ Appendix 1) 2) Analysis of the questionnaire data and the organization of data in analytical tables 3) Development of technical proposals for water supply and sanitation 4) Preliminary Cost Estimate 5) Application of the items on the plan and hydraulic calculations

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7. CONCLUSIONS AND RECOMMENDATIONS

Lack of engineering infrastructure of water treatment and sanitation is a clear limitation for any settlements development, including agriculture. On an example, you can explicitly Vistino trace the relationship between population, development of the industrial zone "Ust‐Luga" and plan infrastructure organizations. Investment options calculations presented in this paper suggest public investment in utility infrastructure and co‐financing of industrial and logistics enterprises. For successful implementation of the plan requires a direct part of administration of rural settlements, and monitor the implementation of the federal government. In technological solutions in water treatment and disposal of scenarios used several different equipment. Different scenarios imply the possibility of choice for tenders and selection of the optimal set of equipment. The practical value of this work is to describe the current algorithm is exhaustive documentation of the pre‐stage. With this document, the administration of rural settlement "Vistino" get a complete picture of network description of repair options, the possibilities of using different types of water treatment equipment and wastewater treatment equipment. Besides the developer spent counting the cost of reconstruction of networks and equipment to the optimal solution. This work can be applied as an example to perform the same projects. On the basis of the calculation tools can perform similar work.

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APPENDIX 1: Questionnaire

SECTION 1 General Information

1 The name of the operating organization (if there are several ‐ list all) ownership, the amount of the authorized capital, shareholders, Name Telephone manager, a technical specialist who can give an explanation to the application form, e‐mail.

2 Since when operating organization is engaged in operation of housing facilities. Validity of this Agreement for the operation.

3 Tariffs for tap water, sewage, heating, electricity, waste sludge from the site over the past 3 years

4 Payroll per month (if it is not a trade secret)

5 Monthly turnover organization ‐ profit ‐ loss, constant energy costs, tap water, heating buildings, solid waste removal, maintenance of equipment.

6 Person supervising the actions of the operating organization by the administration of the settlement. Contact tel., Name, e‐mail

7 Assessment of the overall financial condition of the organization ‐ (stable, needs subsidies). Does the organization currently involved in litigation (if so in what capacity), filing for bankruptcy?

8 What amount of subsidy required and what you plan to spend the allocated funds (current repair, reconstruction, purchase new equipment, design, energy audits, technical survey) what and how much

9 The number of permanent employees of the organization to determine the overall functional (operational maintenance teams, drivers, engineers, management, accounting, lawyers)

10 The presence of an organization owned liquid assets for collateral, credit availability and obligations requiring payment. Timing and extent of the obligations payment schedule.

11 What settlements serves business, the number of inhabitants of these settlements. Fund decent housing secured sewage and water supply networks in m2

12 Availability of industrial enterprises (mv catering) in the territory served by the organization.

13 What services does the organization of the public and what the monthly turnover from these services. Percentage of non‐payers and average receivables per month by type of service.

14 Does the organization have experience with grants, international environmental organizations. Do staff fluent in English, if he can carry on correspondence without a dictionary.

15 Financial statements for the three reporting periods

16 Comprising the organization member companies, partnerships, SROs, NP and TP.

17 Does the organization license approvals. Does the organization passed certification (ISO, OHSAS), check whether the organization was held in the past 3 years, what are the results of the inspections, is there any of the provisions (tax inspection, SES, MEP etc). Attach legal requirements in PM

SECTION 2 Sewage networks

1 The total length of sewer, material execution pipes, pipe diameter (this information is to be divided by areas if used different tubes). Years commissioning sites collector length plots

2 Number of sewered houses, apartments, houses. Number of subscribers, residents enjoy total sanitation

3 How many houses of the total number of dwellings connected to sewage

4 What are the losses on the network utilities. How is the infiltration (entering additional storm water sewers) which increase revenues wastewater can be expected during a heavy downpour in the summer, during snowmelt and spring floods.

5 What is the number of accidents and sewer breaks for the past 3 years, the presence of spills, the number of blockages and causes.

6 What state sewage collector? What wear% by pipe sections. What quantity of pipes require replacement in the near future, what is the diameter

7 Cost of laying one meter diameter pipes required in the prices of the operating organization (cost "turnkey" taking into account all possible costs

8 What is the affiliation of land on which the collector is (private, municipality) and if, then another ‐ specify how many meters and on what grounds.

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9 What used wells for water disposal network, their status deterioration in%, material performance, amount. What number of wells require replacement or rehabilitation (pereobvyazki, futirovki, replace the lid)

10 What types of valves and other shut‐off valves are used on the network ‐ the material execution of the brand. Their diameter is, the state need replacement or repair. Repair Cost (if rated)

11 What amount of CND used on a network, bandwidth, current load condition, deterioration, damage description and requirements for reconstruction, reconstruction costs (if assessed). What pumping equipment used on the network. Number of pumps, brand power. Place the pump pumps condition, how many require replacement or restoration engines. The replacement cost for each object (if rated)

12 What metering devices are on the network, their brand, condition, need to replace, install additional devices. The cost of new equipment and installation (if evaluated). By whom and how the information is gathered and processed accounting of wastewater

SECTION 3 Sewage Treatment Plant (WWTP)

1 The design capacity of the WWTP, commissioning year. Land area occupied by CBS, property belonging land and buildings. Electricity consumption, brand and quantity of consumed reagents (if applicable). Amount of tap water consumed. What requires otpoplenie in winter?

2 Who and how regularly analyzes effluent quality. Bring water analysis protocols in the receiving chamber and the release of CBS (anal protocols). Does the laboratory based operating organization, whether it is accredited, what types of analysis holds.

3 Amount of waste received for 24 m3 Minimum and maximum value of intake flow. Are there seasonal variations in income depending on the number of subscribers who come for the summer? Their volume?

4 Have salvo emissions to the network? Were there cases of mass death of sludge? What chemicals, heavy metals, oil fall in stock? Whether there was an investigation into these cases? What is the result

5 What amount of excess sludge produced per month? How to organize its storage and / or disposal.

6 Observed whether the access mode on sanitation facilities? Is there security facility, video surveillance?

7 Whether in the management of CBS telematic equipment remote control processes?

8 How and where performed issue effluent? Do nearby pond? What category? What's it called? Is there a relationship between output and pond. In the area of release observed "bloom" reservoirs. Is there a possibility of getting treated wastewater into water intake

9 Evaluated whether the cost of measures for the reconstruction and repair or replacement of equipment and CBS? If yes, please specify (the cost of design, procurement, construction) give the project calculation

10 Describe the technological scheme of purification stages.

11 What pumps and blowers used in CBS, quantity, type, brand, condition, need to replace the current consumption.

SECTION 4 Water Network

1 The total length of the water supply network, pipe material, pipe diameter (this information is to be divided by areas if used different tubes). Years of commissioning of the pipeline sections with length up to sites of internal networks. According to in‐house networks can give a general report on the state and the number of networks that need to be replaced, if possible cause payment amount and cost of replacement)

2 Number of houses, apartments, houses. Number of subscribers (people ‐ residents) using common plumbing

3 How many houses of the total number of dwellings connected to the water supply

4 What are the losses on the mains water supply. How is the additional water pollution during transport depending on the state of the pipeline?

5 What is the number of accidents and tears running water for the past 3 years, cracks, blockages and causes of their number.

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6 What is the state of the main pipe treated water from WTP to the first distribution substation? What wear% by pipe sections. What quantity of pipes require replacement in the near future, what is the diameter

7 Cost of laying one meter diameter pipes required in the prices of the operating organization (cost "turnkey" taking into account all possible costs)

8 What is the affiliation of land on which the pipeline is (private, municipality) and if, then another ‐ specify how many meters and on what grounds.

10 What types of valves and other shut‐off valves are used on the network ‐ the material execution of the brand. Their diameter is, the state need replacement or repair. Repair Cost (if rated)

11 What amount of WPS (first, second ascent) used on a network, bandwidth, current load condition, deterioration, damage description and requirements for reconstruction, reconstruction costs (if assessed). What pumping equipment used on the network. Number of pumps, brand power. Place the pump pumps the state, how many require replacement or restoration engines. The replacement cost for each object (if rated)

12 What metering devices are on the network, their brand, condition, need to replace, install additional devices. The cost of new equipment and installation (if evaluated). By whom and how the information is gathered and processed accounting of wastewater

SECTION 5 Sewage Treatment Plants Water Treatment (WTP)

1 The design capacity of the WTP, commissioning year. Land area occupied by the WTP, property belonging land and buildings. Electricity consumption, brand and quantity of consumed reagents (if applicable). Requirement of tap water to rinse the filter. What requires otpoplenie in winter?

2 By whom and with what regularity conducted analyzes of water quality. Bring water analysis protocols. Does the laboratory based operating organization, whether it is accredited, what types of analysis holds.

3 The amount of water supplied to the network 24 m3 hour minimum and maximum value of intake flow. Are there seasonal variations in consumption, depending on the number of subscribers who come for the summer? Their volume?

4 Is the pressure in the network (for network sections) what information there is a loss of pressure in the pipeline for sites.

5 Observed whether the access mode on objects WTP? Is there security facility, video surveillance?

6 Whether management WTP telematic equipment remote control processes?

7 How and where is carried out with the release of wash water filters? Do nearby pond? What category? What's it called? Is there a relationship between output and pond. Which potentially hazardous pollution shall issue?

8 Evaluated whether the cost of measures for the reconstruction and repair or replacement of equipment and WTP? If yes, please specify (the cost of design, procurement, construction) give the project calculation, give priority repairs

9 How is the additional contamination of treated water from contact with equipment WTP (corrosion of pipelines, wall filters, removal of backfill)

10 Describe the process flow diagram of the WTP, provide water treatment stages

11 What pumping equipment used in the composition of the WTP their number, type, model, condition, need to replace the current consumption.

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