In the national and international context, two general concerns revolve around water treatment processes. First of all, we talk about energy efficiency and environmental compatibility in the water treatment plants that should be continuously improved for rational energy use and renewable energy sources implementing [1]. Thus, the environmental objectives as reducing CO2 emissions and improve energy efficiency are major concerns today. The purpose of this paper is to conduct a study on a water treatment plant and to develop solutions that will lead to the efficiency improvements of water treatment process in energy consumption terms.
By applying the Polyfactorial equation methodology, we can find out the environmental impact of the water treatment process. The total energy demand of water treatment plant Barati (WTP Barati) which treats the water of the city of Bacau was evaluated at 239.94 MW h/y and the highest energy consumption is registered by the technical building, which represent 40 % from total energy consumption. Another important aspect in case of Bacau water treatment plant is the raw water turbidity, which influences energy quantity used for treatment process.
The results analysis has highlighted two main conclusions of water treatment plant. The weakest point of the WTP Barati is the water distribution system. These are outdated and affect the treated water quality until it reaches the consumer. The biggest strong point is the raw water quality, which during the winter period reaches a very high level of quality, requiring only a simple chlorination in the treatment system

Emilian MOSNEGUȚU

Florina FABIAN

Narcis BÂRSAN

Valentin NEDEFF

The Annals of “Dunarea de Jos” University of Galati Fascicle IX Metallurgy and Materials Science

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THE ANNALS OF “DUNAREA DE JOS” UNIVERSITY OF GALATI 
FASCICLE IX. METALLURGY AND MATERIALS SCIENCE 
No. 3 - 2017, ISSN 1453-083X 
 
 
 
 
 
ENERGY CONSUMPTION ASSESSMENT IN THE WATER 
TREATMENT PROCESS, BACĂU CITY CASE STUDY 
 
Florina FABIAN*, Valentin NEDEFF, Narcis BÂRSAN, 
Emilian MOSNEGUȚU 
“Vasile Alecsandri” University of Bacau, Romania, 600115, Bacau, Romania 
e-mail: florina.fabian@yahoo.com 
 
ABSTRACT 
 
In the national and international context, two general concerns revolve 
around water treatment processes. First of all, we talk about energy efficiency and 
environmental compatibility in the water treatment plants that should be 
continuously improved for rational energy use and renewable energy sources 
implementing [1]. Thus, the environmental objectives as reducing CO2 emissions 
and improve energy efficiency are major concerns today. The purpose of this paper 
is to conduct a study on a water treatment plant and to develop solutions that will 
lead to the efficiency improvements of water treatment process in energy 
consumption terms. 
By applying the Polyfactorial equation methodology, we can find out the 
environmental impact of the water treatment process. The total energy demand of 
water treatment plant Barati (WTP Barati) which treats the water of the city of 
Bacau was evaluated at 239.94 MW h/y and the highest energy consumption is 
registered by the technical building, which represent 40 % from total energy 
consumption. Another important aspect in case of Bacau water treatment plant is 
the raw water turbidity, which influences energy quantity used for treatment 
process.  
The results analysis has highlighted two main conclusions of water treatment 
plant. The weakest point of the WTP Barati is the water distribution system. These 
are outdated and affect the treated water quality until it reaches the consumer. The 
biggest strong point is the raw water quality, which during the winter period 
reaches a very high level of quality, requiring only a simple chlorination in the 
treatment system. 
 
KEYWORDS: water treatment, energy consumption, carbon footprint, energy 
efficiency 
 
1. Introduction 
 
Considering everything that is happening 
worldwide, water has become the main element in all 
activities and life support on this planet. When we say 
the main element of all the activities we refer to 
population, food, industry, irrigation, cleaning. In 
their turn non-recoverable waste from these sectors of 
activity is often thrown into the water [2]. 
Finally, water potabilization means removing 
most of organic, inorganic and biological 
components. The water source of a city can be 
groundwater or surface water (rivers, lakes etc.). 
The water source for drinking water in the town 
Bacau is Poiana Uzului Lake, the main purpose being 
water supply and electricity production. The dam is 
84 m high, 507 m long and the lake has a length of 
3.75 km, an area of 334 hectares and a volume of 98 
million cubic meters. Maximum depth of the lake is 
64.7 m. The lake is located at a distance of 60 Km SE 
form Bacau and is situated in Nemira Mountains 
(Figure 1); also, this lake is not affected by industrial 
pollution [3]. 
In general, each human being and everything 
that is happening on this earth have an impact on the 
environment, and also the most relevant impact on the 
environment in water treatment process is related to 
energy consumption, and if we want to speak about 
energy efficiency in water treatment process we need 
to consider the following factors: rational use of 
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THE ANNALS OF “DUNAREA DE JOS” UNIVERSITY OF GALATI 
FASCICLE IX. METALLURGY AND MATERIALS SCIENCE 
No. 3 - 2017, ISSN 1453-083X 
 
 
 
energy (mixing time, type of mixer), implementing 
renewable energy sources, the use of high efficiency 
machines, the use of advanced water treatment 
technologies (nanofiltration, reverse osmosis, 
granular activated carbon) [4]. This study aims at 
finding out the environmental impact of water 
treatment process regarding the energy consumption. 
 
 
 
Fig. 1. Poiana Uzului Lake 
 
2. Evaluation method 
 
Environmental impact of the water treatment 
process regarding the energy consumption can be 
analyzed through several methods, for example: 
Carbon Footprint methodology, Externalities of 
Energy, Polyfactorial equation methodology. In the 
present case study, we will use the Polyfactorial 
equation methodology, where we consider different 
factors [5]: the quantity of energy used for water 
treatment, working regime, type of flocculant, process 
and water treatment equipment, sedimentation time 
and, finally, we make different scenarios. For 
example, the following scenario: we have water 
treatment plant (WTP Bacau) and equipment from 
Bacau where we vary the quantity of energy and 
chemicals (Figure 2), working regime, type of 
flocculant and sedimentation time. 
 
 
 
Fig. 2. Polyfactorial equation methodology 
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THE ANNALS OF “DUNAREA DE JOS” UNIVERSITY OF GALATI 
FASCICLE IX. METALLURGY AND MATERIALS SCIENCE 
No. 3 - 2017, ISSN 1453-083X 
 
 
 
Water Treatment Plant from Bacau is composed 
of the following units’ components [3]: 
- raw water intake and distribution chamber; 
- rooms of flowmeters in the form of tanks made 
of reinforced concrete; 
- fast mixing tanks, flocculation tanks and 
clarifiers lamellar; 
- fast sand filters gravitational; 
- chlorine contact tank; 
- wash water tank; 
- sedimentation tank dirty water from washing 
the filters; 
- building support processes and control services 
- chamber of sludge collection; 
- chlorination building consisting of chlorine 
storage room, preparation chlorine concentration 
room, neutralization chamber; 
- office building. 
This unit components are grouped as shown in 
Table 1 [3]: 
 
Table 1. Structure of Water Treatment Plant Bacau 
 
Point Description Structure 
MCC 101 
 
Inlet Works and Clarifier 
 
Pressure Switch for Recycling Pumps 
Pressure Switch for Supernatant Pumps 
Sludge Tank Ultrasonic Level Meter 
Used B. Water Tank Ultrasonic Level Meter 
Inlet Flowmeter  
12 Pcs Sludge Pneumatic Valve  
Turbidity Meter 
3 Pcs Clarified Sample Water Solenoid Valves  
PLC 
MCC 102 
 
Filtration 
 
Pressure Switch for Backwash Pump (3 pieces) and Cl 
Driving Pump (2 pieces) 
Pressure Switch for Booster Set 
Air Compressor (2 pieces) 
Overhead Crane 
Fan Coil (Heating) (2 pieces) 
Level Switch for Drainage Sump (2 pieces) 
Wash Water Discharge Valve  
Wash Water Discharge Flow Meter 
Turbidity Meter (2 pieces) 
Backwash Water Ultrasonic Level Meter 
8 Pcs Filtered Sample Water Outlet Valves  
PLC Panel 
Lighting Panel LP-FB 
MCC 103 
 
Chlorination 
 
Overhead Crane 
Air Ventilation Fan Storage Room (2 pieces) 
Air Ventilation Fan 1 Chlorinator Room 
PLC Panel 
Lighting Panel LP-CB 
MCC 104 
 
Chemicals 
 
Alum Solution Discharge Flowmeter (4 pieces) 
Al Dilution Water Solenoid Valve (4 pieces) 
Level Switch Alum Tank (2 pieces) 
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THE ANNALS OF “DUNAREA DE JOS” UNIVERSITY OF GALATI 
FASCICLE IX. METALLURGY AND MATERIALS SCIENCE 
No. 3 - 2017, ISSN 1453-083X 
 
 
 
Pressure Switch for Lime Circulating Pump (2 pieces) 
Lime Dosing Solenoid Valve (6 pieces)  
Level Switch Lime Tank (2 pieces) 
Pressure Switch for PAC Circulating Pump (2 pieces) 
Solenoid Valve 1 (Pack Dosing) (3 pieces) 
Level Switch PAC Tank (2 pieces) 
Polymer Preparation & Dosing Unit 
Polymer Solution Discharge Flowmeter (4 pieces) 
Polymer Dilution Water Solenoid Valve (4 pieces) 
Sampling Pump No (3 pieces) 
Inlet Flowmeter Reservoir (3 pieces) 
Outlet Flowmeter Reservoir (3 pieces) 
Overhead Crane 
Reservoir Ultrasonic Level Meter (3 pieces) 
Lime Ventilator 
Pac Ventilator 
Lime Dosing Line Solenoid Valve (4 pieces) 
Pac Dosing Line Solenoid Valve (4 pieces) 
PLC panels 
Lighting Panel LP-CH 
105 Technical Building 
 
Boiler 
Circulation Pump (2 pieces) 
Laboratory Equipment  
pH & Conductivity Meter Water Analyzer Group 1 
Conductivity Meter Analyzer Group 1 
Residual Chlorine Meter Analyzer Group 1 
pH & Conductivity Meter Water Analyzer Group 2 
Conductivity Meter Analyzer Group 2 
Residual Chlorine Meter Analyzer Group 2 
Raw Water Sample Water Solenoid Valve 
Chlorine Contact Tank Sample Water Solenoid Valve 
Reservoir 1 Sample Water Solenoid Valve 
Reservoir 2A Sample Water Solenoid Valve 
Reservoir 2B Sample Water Solenoid Valve 
PLC panels 
Internal Lighting LP-TB 
External Lighting Panel LP-OL 
*MCC - Motor Control Centers 
 
3. Results and discussion 
 
The scheme of water treatment plant of Bacau is 
structured according to the nature and characteristics 
of the raw water, as well as the qualitative conditions 
demanded by consumers' needs, following the most 
economical and safer operating solutions [6]. The 
water treatment plant Barati from our case study 
recorded, over the monitored period of the 12 months 
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THE ANNALS OF “DUNAREA DE JOS” UNIVERSITY OF GALATI 
FASCICLE IX. METALLURGY AND MATERIALS SCIENCE 
No. 3 - 2017, ISSN 1453-083X 
 
 
 
of 2015, an electrical energy consumption (Table 2) 
of about 239.94 MWh/year [7]. 
As can be seen (Figure 3) in the case of water 
treatment process in Bacau, the highest annual energy 
consumption is recorded in the filtration phase, 
representing more than 20 % of the total energy 
consumption. 
The amount of energy consumed for 
groundwater extraction is unique to each water 
system, ranging from the low energy requirements of 
a gravity feed system to the high energy requirements 
of an inverse osmosis system pumped by sea [8]. 
 
Table 2. Structure of Water Treatment Plant Bacau [7] 
 
Point Description MWh/year 
MCC 101 Inlet Works and Clarifier 10.77 
MCC 102 Filtration 50.13 
MCC 103 Chlorination 33.39 
MCC 104 Chemicals 48.48 
105 Technical Building 97.17 
TOTAL POWER MW h/year                                                               239.94 
 
 
 
Fig. 3. Energy consumption for WTP Barati – 2015 
 
The connection of the equipment to the power 
supply from the water treatment plant Baraţi is made 
to the local network and the consumption depends on 
the turbidity of the raw water as can be seen in Table 
3. 
As far as energy efficiency and environmental 
compatibility are concerned, water treatment plants 
are continuously improved for rational use of energy 
and the implementation of renewable energy sources. 
Thus, environmental objectives such as reducing CO2 
emissions and optimizing energy efficiency are the 
main preoccupations. Using advanced efficiency 
machines, advanced water treatment technologies, it 
is possible to achieve additional synergies to reduce 
energy consumption [8]. 
 
Table 3. Energy consumption and water turbidity 
 
Electricity consumption 
Process equipment 
Average effective 
flow, m3/d 
Guaranteed unit 
electricity 
consumption, kWh/m3 (60 000 m3/d) 
Raw water NTU 1 - 10 30,000 0.02726 
Raw water NTU 10 - 20 21,000 0.02726 
Raw water NTU 20 - 70 9,000 0.02726 
 
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THE ANNALS OF “DUNAREA DE JOS” UNIVERSITY OF GALATI 
FASCICLE IX. METALLURGY AND MATERIALS SCIENCE 
No. 3 - 2017, ISSN 1453-083X 
 
 
 
4. Conclusions 
 
The case study in this research work is focused 
on the Baraţi water treatment plant located on the 
Barati hill of the commune Măgura, located at a 
distance of approx. 6 km from Bacau where the 
quality of raw water at the entrance in water treatment 
plant, the quality of the treated water at the exit of 
storage tank and the amount of energy consumed for 
water treatment were analyzed and monitored for 12 
months (2015). 
Analyses of water sources are carried out 
(surface waters / groundwater) if they are affected by 
industrial pollution or not, in order to distribute water 
to the population. Depending on the physico-chemical 
characteristics of the water, it will go through the 
water treatment process, which includes a series of 
stages determined by the level of water pollution. 
The evolution of freshwater consumption 
confirms human evolution, so if at the beginning of 
the last century the average consumption reached 
only 240 cubic meters over the whole lifetime of an 
individual, in the last years it has tripled, according to 
modern living standards. 
Certainly, the main cause, which determined the 
ascending curve of current water needs and 
consumption, is technical progress, so that industry 
and agriculture swallow most of the world's water 
consumption [9]. The crisis of fresh water resources 
and especially their efficient management has become 
among the most important issues of the contemporary 
world. 
 
References 
 
[1]. Bickel P., Friedrich R., Externalities of Energy, Methodology, 
Update, European Commission, Stuttgart, Germany, 2005. 
available at: http://ec.europa.eu/research/energy/pdf/kina_en.pdf 
(accessed: 07.10.2016). 
[2]. Barrios R., Siebel M., Helm A., Bosklopper K., Gijzen H., 
Environmental and financial life cycle impact assessment of 
drinking water production at Waternet, Journal of Cleaner 
Production, Amsterdam, Netherlands, vol. 16, p. 471-476, 2008. 
[3]. ***, The Environment Agreement for the construction of water 
treatment plant Bacau, Environmental Protection Bacau Agency 
Bacau, 2007. 
[4]. Pankaj B., Brown A., World Resources Institute, World 
Business Council for Sustainable Development, Greenhouse Gas 
Protocol, Product Life Cycle Accounting and Reporting Standard, 
vol. 1, p. 18-20, 84, 2011. 
[5]. ***, Proiect de reglementare tehnică, Normativ privind 
proiectarea, execuţia şi exploatarea sistemelor de alimentare cu 
apă şi canalizare a localităţilor. Indicativ NP 133–2011, Available 
at: http://novainstal.ro/tratarea-apei-potabile/, (accessed 
30.11.2016). 
[6]. ***, http://novainstal.ro/tratarea-apei-potabile/(accessed on 
06.5.2015). 
[7]. Roessler W. G., Brewer C. R., Permanent turbidity 
standards, Appl. Microbiol., 15, p. 1114-1121, 1967. 
[8]. Koomey J., Krause F., Introduction to Environmental 
Externality Costs, CRC Handbook on Energy Efficiency, USA, 
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[9]. ***, WABAG Company, Annual report 2015-2016, no. 17, 
available at: http://www.wabagindia.com, (accessed: 30.11.2016). 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
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Energy Consumption Assessment in the Water Treatment Process, Bacău City Case Study

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Energy Consumption Assessment in the Water Treatment Process, Bacău City Case Study

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