Rapid urbanisation brings about increase in air pollution. These emissions are generally linked to the production of energy, to industrial activities and to transport in the densely inhabited areas. Estimating the pollutants quantities released in the air is an important stage in the evaluation of air quality. However, the problem of air pollution in urban areas is a problem in all Algerian cities. Similar to all Algerian big cities, the city of Batna has become a major urban area with an ever increasing fleet of motor vehicles most of which are practically old ones. This state of affairs increases the demand in fuel consumption and undeniably intensifies polluting emissions. As the situation goes, it has become the utmost urgency to wonder about a possible support that may be given to this sector in order to evaluate how air quality is managed in a durable way. The main objective of this study is to assess the quantity of CO 2 pollutant known as the most significant greenhouse gas emission from traffic. The approach used is mainly based on a number of assumptions, which allows us to find the amount of 192 g/km/day CO 2 released into the urban atmosphere of the city of Batna.
During the last decade, societies have witnessed greater industrial growth and disproportionate energy consumption which have brought about emission of greenhouse effect gas (GEG). Therefore, these societies face serious problems due to air pollution such as greenhouse effect or human health problems [
Atmospheric pollution generated by road transport constitutes a real public health issue that should be handled by the authorities both at a regional and an urban level [
Moreover, the interest in the nuisances of car traffic has gradually changed into a real concern in societies [
Motor vehicles are indeed the cause of many externalities such as air pollution, traffic jam, noise and lack of road safety. The latter is a universal problem that causes a lot of human casualties and material damage. This has pushed the WHO to stress the importance of such an impact and to declare the period 2011-2020 as “the decade of action for road safety” [
However, emissions caused by traffic or indirectly generated by photochemical reactions will remain one of the main sources of pollution in urban areas and constitute a serious danger for human health [
In Algeria, as in most countries, there is more and more consideration of the degradation of air quality in urban environment and its impact on public health because of road traffic [
Polluting emissions of motor vehicles constitute not only a problem for the quality of air in cities like Algiers [
The city of Batna, as one of the big Algerian cities, is not an exception. Knowing that this city has become a metropolis and glancing at the fleet of motor vehicles it contains, one cannot help noticing anomalies that raise highly important questions concerning public health and the preservation of the environment. In the absence of any previous study that deals with this type of pollution in the city of Batna, this work aims at investigating the polluting emissions that are caused by road traffic and their impact on air quality in the city of Batna.
Batna, as an urban area, has presently become a big centre with people moving in and out causing weak mobility and sometimes traffic jams especially at the rush hours. Transport changes occur mostly at the city centre where there is the greatest rate of urbanization (89.4%) [
A further problem is that the mobility rate of property and people may lead to development and progress and
may cumulate in delays that cause partial or global congestions. The places of such congestions differ in their evolution and have complex causes. As it is the case of all cities, the city centre has many streets with extremely dense traffic in comparison with their width and the state of their roads. We must also note that there is growing congestion in ring roads as well.
In this respect, we carried out an investigation (during two years 2012-2013) in order to estimate the number of motor vehicles which access the city through its main entrances and which constitute an agravating factor of road congestion. The results reinforce this hypothesis [
The investigation consisted of selecting the roads that are representative in terms of the flow and density of traffic as well as the type of road (main, secondary and tertiary) taking into account that the city of Batna has been divided into 7 areas, in accordance with the municipal code (
We had to spend two years of field investigation and assessment in order to select the area to study and determine the daily average rush hour (figure 2). This allowed us to decide on an average that is reproducible, significant and representative of what remains of our work.
The obtained results are illustrated in table 1.
Areas Roads | Area 1 | Area 2 | Area 3 | Area 4 | Area 5 | Area 6 | Area 7 |
---|---|---|---|---|---|---|---|
Main Road (Vehicle) | 539.33 | 208 | 257 | 231.66 | 327 | 345.66 | 374.33 |
Secondary Road (Vehicle.) | 334.33 | 230 | 181.33 | 103.66 | 278.66 | 85 | 120.66 |
Thirtiary Road (Vehicle.) | 239.33 | 129.33 | 121 | 28.66 | 81.33 | 26 | 88.33 |
Average Vehicle | 1112.99 | 567.33 | 559.33 | 363.98 | 286.99 | 456.99 | 583.32 |
Average Rush Hour (mn) | 10 10.66 5.16 | 4.83 7 34.33 s | 8.16 11 7.66 | 11 8.33 6.33 | 13.66 8.33 6 | 5 3 4 | 8 9.66 6.66 |
Our approach consists of acquiring data which have a link with spatio-temporal dimensions.
The processing of these data is summarized in figures 2-6.
In order to quantify the impact of these pollutants, we have recourse to the emission factors which allow us to estimate their concentrations. This approach will allow us to estimate the CO2 concentration in proportion to a limited space.
To estimate the quantity of the released CO2, we determine the temporal space, in accordance with the obtained results of our investigation i.e. the number of vehicles, the trail distance and time as well as the number of vehicles running during the rush hour (table 2).
If we suppose, according to the OEE (Office of Efficiency Energetics, Ecoflootte Program), that a vehicle consumes 4 litres of fuel per hour, the overall number of vehicles will consume 1915, 844 litres of fuel. According to the Direction of the Reglementation and General Administration (DRAG), 49.38% of all vehicles consume petrol and the rest consume diesel. Considering the density of diesel and petrol, which are 0.845 and 0.755 respectively, and in order to determine the quantity of the consumed carbon by both fuels, we use the two emission factors namely 20.20 tons per terra joule for diesel and 18.90 tons per terra-joule for petrol. By resorting to the Terra-joule unit and considering that 99% of carbon is oxidized, the emission contents of carbon in diesel and petrol are 0.733 and 0.592 tons respectively.
Furthermore, the overall quantity of CO2 released in the city, during the year 2013, where there is an average number of vehicles of 95,239 (table 3) is 1140118.01 tons of CO2. This is considering that a vehicle runs an average of 170 km/day, a petrol vehicle consumes an average of 6.7 liters/100km and a diesel one consumes 8.46 liters/100km.
The work that has been undertaken, concerning the city of Batna is to verify hypotheses taking into account the number and the categories of motor vehicles as well as the distance run and the average fuel consumption. It has allowed us to estimate the role of pollutants emissions with greenhouse effect which are generated by the road transport sector.
We note a certain number of problems caused by demographic growth, the saturation of the road network, the old age of the motor vehicle fleet and traffic congestion. These lead to deterioration of air quality with an impact on human health, degradation of the ecosystem and especially reduction of life quality.
In Batna, the consequences of atmospheric pollution start to weigh on the population by an unbreathable atmosphere leading to an increase in respiratory diseases. This is caused by the release of allergens in the environment by engines, exhaust pipes, air conditioners and worn tyres, particularly in areas where traffic is very
dense. It is estimated that more than 50% of emissions are caused by road transport as the city is not very industrilized and there is constant increase in the sales of fuel.
The urban air quality is essentially linked to the type of motor vehicles, the quality of the engine and fuel, the presence of a catalytic converter, the transported load and the speed of the vehicle. The speed is reduced in an urban area where traffic is in constant increase, which favours the emission of CO2, CO, NOx and PM due to overconsumption of fuel with reduced movement efficiency. These result in pollution peaks with the impacts that characterize each pollutant [
Category | 1973-1992 | 1993-1997 | 1998-2002 | 2003-2007 | 2008-2012 |
---|---|---|---|---|---|
VP | 40 | 17 | 163 | 131 | 232 |
VUL | 0 | 1 | 12 | 8 | 32 |
Bus | 5 | 3 | 7 | 2 | 1 |
Energy Source | Number of Vehicles/Year of Traffic | ||||||||
---|---|---|---|---|---|---|---|---|---|
2005 | 2006 | 2007 | 2008 | 2009 | 2010 | 2011 | 2012 | 2013 | |
Diesel | 11,443 | 13,764 | 16,739 | 19,722 | 22,639 | 25,024 | 32,830 | 35,728 | 58,110 |
Petrol | 19,836 | 21,362 | 23,916 | 26,979 | 29,844 | 32,549 | 44,281 | 47,816 | 37,129 |
In order to reinforce the obtained results a second method proves useful and which starts from the following hypotheses:
· An average motor vehicle produces between 100 and 300 m3 of exhaust pipe gas per hour;
· There are 3 phases during day time which represent the rush hour periods and which equal 1 hour/day of maximum traffic;
· A light motor vehicle produces 0.02 tons of CO2 for each 100 km run;
· In all cases, the maximal values are kept.
In order to be able to compare the two results using the two methods, we will consider the same number of vehicles which is 95,239 in the year 2013 and we will assume that a vehicle runs as an average distance 170 km/day; we find a daily emission of 3238.126 tons. This corresponds to a total yearly emission of 1,181,916 tons of CO2. We notice that when using the two methods the results match perfectly with an error coefficient of 3.53%.
Moreover, using the pollutants emission factors: CO, NOx and PM2.5 which are: 7.5, 0.64, and 0.060 g/km/veh respectively [
In order to match the situation with the various norms and limiting the concentrations of the various pollutants released linked to urban transport, we had to recalculate the emissions only for private vehicles for the year 2013. They constitute 66.35% of the overall motor vehicle fleet (figure 4). The result is a CO2 emission of 192 g/km/day relatively higher than the European norm, which is 130 g/km/veh CEE (the European Commission on CO2 emissions from cars).
Concerning CO, we find the 11.446 g/km.veh value which is relatively higher than the Algerian norm, somewhere between 1 and 2.3 g/km/veh [
Finally, concerning the average content of particles (PM), the calculated value is 0.091 g/km/veh, which ex-
Years/Tons | 2005 | 2006 | 2007 | 2008 | 2009 | 2010 | 2011 | 2012 | 2013 |
---|---|---|---|---|---|---|---|---|---|
CO2 | 377763.68 | 423628.12 | 489678.89 | 562115.69 | 631338.67 | 692424.71 | 927082.11 | 1004124.85 | 1140118.01 |
NOx | 12.42 | 13.95 | 16.14 | 18.54 | 20.84 | 22.86 | 30.62 | 33.17 | 37.82 |
PM | 1.16 | 1.31 | 1.51 | 1.74 | 1.95 | 2.14 | 2.87 | 3.11 | 3.54 |
CO | 145.56 | 163.46 | 189.20 | 217.33 | 244.24 | 267.93 | 358.85 | 388.79 | 443.21 |
ceeds the de 0.05 g/km/veh norm [
In addition, many studies dealing with this problem have been achieved. For instance, the evaluation carried out at the loir-cher—France department [
The technical efforts to reduce the CO2 emissions have proved useless so far because they remain closely linked to the fuel consumption volume. That is why action should bear directly on car driving and notably on the traffic volume and requires a good understanding of the evolution of the motor vehicle fleet and the human need of movement.
Road transport is more and more important nowadays with the increase in the number of motor vehicles. The impact of road transport evolution on air quality is significant. Its consequences are in terms of a higher number of accidents, hazards to public health, urban saturation, overconsumption of non-renewable energy and landscape deterioration.
The rapid and disproportionate urban growth of the city of Batna has had negative impacts on its traffic projects leading to overloading some traffic axes, reducing mobility, and on the other hand, to traffic congestions particularly at the rush hours. These forcibly imply over consumption of fuel, increase in atmospheric and sound pollution, and emission of CO2 is higher than ever. Extrapolating these results for 2020, increase of CO2 by 75% is shown. The same extrapolation is carried out for the Algerian capital for 2020, which gives 2.3 million tons of CO2 [
In order to face up to this type of problem, there may be many solutions. At a local level, a certain number of adjustments are necessary in terms of motor vehicle traffic management especially at the most significantly hot spots. There ought to be better road signals, controlled parking areas newly thought and reflected upon transport and traffic plans and more encouraging measures by the authorities for the use of less polluting fuel such as LPG and natural gas for vehicles (GNV).
This study has permitted assessing the impact of transport on air quality. The task then is to establish a balance between the mobility of urban transport and the caused rate of urban pollution.
A more profound study would be necessary in order to determine the distribution and the lifespan of the pollutants with regard to the global city in order to set the appropriate mapping.
Finally, the city of Batna has to take necessary measures in order to reduce greenhouse effect gas emissions (GEG) and harmful pollutants while elaborating the necessary tools for supervising and assessing air quality and its future evolutions. Such assessments will be at the disposal of the local authorities and decision makers.