1. Introduction
One of the consequences of the industrial development is air pollution, which is rising due to the increase in city populations, the high consumption of fossil fuels and the widespread use of private cars. Air pollution causes a lot of health and environmental problems. Specifically, it has been calculated that there are around 500,000 premature deaths per year in Europe due to air contamination [
1]. Also, the highest concentrations of gaseous pollutants are usually located in urban agglomerations.
For these reasons, the quality of the air is one of the major concerns of regional, national and European governments. Authorities are developing strict regulations and controls in order to reduce the emissions of pollutant gases and particles. According to the European Union, these measures should ensure a clean atmosphere, free of anthropogenic contaminants by 2030 [
2].
To analyse the quality of the air, the modelling of the atmospheric contamination behaviour is one of the most important tools. Several software tools have been developed during last years in order to evaluate the air pollution, such as AERMOD [
3], CALPUFF [
4], OSPM [
5]. These tools enable the study of current conditions and, also, the prediction of new situations with a reasonable cost (economic and computational time) in both urban areas and industrial environments with different spatial spans and detail level depending on each software. Usually, they have a closed architecture and most of them are focused on the analysis of the dispersion of specific contaminants such as SO
2, NO
2, PM
10, PM
2.5, Pb, VOC, NH
3 [
1,
6]. These codes use only basic equations of fluid movement, but they include photochemical models and different databases such as air quality, transport, weather and so on.
However, there are other tools, which enable the implementation of these analyses more precisely and without any restrictions. One of the most popular tools is Computational Fluid Dynamics (CFD) designed for the study of fluids in general. Specifically, it is possible to evaluate the dispersion of any substance in different environments, and it is especially useful at small or medium-scales taking into account the orography, buildings, etc. [
7].
This paper describes a methodology based on CFD to study the dispersion of industrial-type air pollutants in a relatively large area. This methodology enables the simulation of 3D geometries taking into account the terrain orography and the study of the effect of the wind around the buildings and other constructions. Also, this tool allows considering the specific characteristics of the industrial contaminants (density, concentration, toxicity, etc.) and the particles if they exist with the pollutants by using specific models.
2. Materials and Methods
The numerical simulations of the dispersion of air pollutants are performed using the CFD code ANSYS, solving the unsteady-state Reynolds averaged Navier-Stokes equations through the finite volume method. With this methodology, 3D geometries can be generated and simulated considering the orography of the terrain with domain dimensions relatively large, or even, the effect of the wind around the buildings, as it can be seen in
Figure 1. Normally, the domains are discretized with unstructured meshes formed by triangular prism cells. These meshes are refined at the regions where there are potentially higher field gradients, such as the atmospheric boundary layer or nearby buildings. The number of cells can vary between 500,000 and 10,000,000 in function of the simulation type.
Once the geometry and mesh have been generated, multi-species models are used to study the mixing and transport of chemical species by solving conservation equations describing convection, diffusion and reaction sources for each component. In this case, there is only a species mixing without chemical reactions. Then, ANSYS predicts the local mass fraction of each species
Yi, through the solution of a convection-diffusion equation for the
ith species. The general form of this conservation equation is:
where,
is the net rate of production of species
i by chemical reaction and
is the rate of creation by addition from the dispersed phase plus any user-defined sources and the diffusion flux of species
i is
for turbulent flows.
Moreover, when these contaminants have particles, the Lagrangian discrete phase model is selected to study their behaviour together with these gases pollutants. This model follows the Euler-Lagrange approach. The fluid phase is treated as a continuum by solving the time-averaged Navier-Stokes equations, while the dispersed phase is solved by tracking a large number of particles through the calculated flow field. The dispersed phase can exchange momentum, mass and energy with the fluid phase. A fundamental assumption made in this model is that the dispersed second phase occupies a low volume fraction, even though high mass loading
is acceptable. The particle trajectories are computed individually at specified intervals during the fluid phase calculation by integrating the force balance on the particle. This force balance equates the particle inertia with the forces acting on the particle, and can be written (for the x direction in Cartesian coordinates) as:
Also, the gravity and the density variations due to thermal changes are taken into account assuming an ideal gas behaviour. Furthermore, turbulent effects in the fluid flow are considered by means of the K-epsilon-RNG model [
8], including buoyancy effects and appropriate boundary conditions are defined. Normally, to represent the domain a velocity inlet condition in the input is used, while the output is represented by a constant static pressure value. Both buildings and bottom surface are considered wall conditions, while the upper and lateral surfaces are considered frictionless walls.
Regarding the solution procedure, a second order discretization scheme is selected for the governing equations at each cell in order to assure good calculation accuracy. Besides, the convergence criterion to conclude the iterative computational process is established in values lower than 10−5 for the normalised residuals of each governing equation.
3. Results
This methodology allows obtaining all details of the dispersion of contaminants (gases and particles) in both cases, large areas and smaller zones with buildings. Furthermore, concerning the results, it offers a lot of possibilities: contours of velocity, temperature, pressure, concentration, etc.; also, isoconcentration 3D maps, velocity vectors, and so on. All these results can be obtained varying with the height, at a specific elevation or in a determined zone. As an example,
Figure 2 shows the concentration of the pollutants in the symmetry zone for two cases, when the contaminant gas is lighter (left) or heavier than the air (right). In the first case, the pollutant gas has a lower density than the air and, as it can be seen, it goes up and dissipates. In the second case, the contaminant gas, at the beginning, it goes up to about 200 m and then, goes back to fall down diffusing and scattering over the surface.
4. Conclusions
The industrial development causes an increase of air pollution, among other things. The pollution provokes a lot of health and environmental problems and therefore, all governments are developing strict regulations and controls to reduce the gases emissions.
The quality of the air can be analyzed by modelling the atmospheric contamination behavior. There are several tools to evaluate the air pollution. In this paper, a methodology based on Computational Fluid Dynamics (CFD) has been described, taking into account the dimensions of the domains, the type of mesh and specific models in order to consider the specific characteristics of the industrial contaminants and particles. Also, among the results obtained, one example has been shown analyzing the dispersion of the gas pollutant when it is lighter and heavier than the air.