The present invention relates to a method of modeling the biodegradation of hydrocarbons trapped in an oil reservoir or trap, through the action of the bacterial population in an aquifer, from data relative to the reservoir studied.
The method according to the invention allows to form an assessment tool particularly useful notably to geologists anxious to direct investigations out of risk areas.
Biodegradation of an oil is an alteration phenomenon caused by the oxidation of certain hydrocarbon molecules by micro-organisms or bacterial flora, which leads to the formation of a heavy oil, therefore difficult to produce and not very cost-effective commercially. The bacteria consume these molecules as they respire and to get the elements essential for their growth and their replication. The study of this phenomenon arouses renewed interest with the development of deep-sea exploration, the presence of heavy oil being a major risk. There are not many means currently available to predict biodegradation risks and to describe this phenomenon, whereas the economic need for the development of quantitative tools is great nowadays.
Biodegradation is a bio-geochemical process similar to a cold combustion performed by micro-organisms. A bacterium capable of degrading hydrocarbon compounds can in fact be considered as a hydrocarbon-consuming machine using electron acceptor ions (that can be compared to an oxidizer) and rejecting reducers.
A first condition for the existence of biodegradation is naturally the existence of these microorganisms. They are present in the medium either since the deposition of the sediment layer at the surface or because they have been brought there by meteoric water. In the absence of petroleum organic matter or of other sources of carbon (CO2, carbonate ions, etc.), the bacteria encyst and can be preserved during very long periods of time.
It is well-known that there are two distinct bacterial mechanisms causing the degradation of organic matter:
Respiration is a permanent process whereas anabolism occurs only at certain points in the life of the bacterium. Only respiration has been studied because it is considered to be preponderant over anabolism in the degradation of hydrocarbons. However, the two mechanisms are not independent. When a bacterium effects its anabolic process, it increases its respiration because it needs much energy.
The table hereafter gives examples of electron sources and acceptors, and of products of the reactions that can be observed in oil reservoirs.
A known biodegradation model of a field from data from the Gullfaks field in the North Sea is described in the following publication:
According to this model, filling of a trap with hydrocarbons is considered with a constant flow. Water saturated with electron acceptors also circulates with a constant flow. The field has a simple parallelepipedic symmetry. During filling in the transition zone, the destruction of four n-alkanes is calculated by means of conventional kinetic laws of the first order obtained in the laboratory. The equational balance consists of a kinetic term of hydrocarbon destruction and the terms of hydrocarbon and electron acceptor supply by convection. The degradation is double, aerobic and by sulfate reduction.
In this system, the electron acceptor supply is the limiting factor. The parameters controlling the system are the thickness of the transition zone, the flow rate of water under the transition zone. The results obtained by this type of model are not really realistic. This is due to the balances and to the reaction kinetics selected, the latter being linked with the lack of knowledge about the bacterial kinetics and the attack mechanisms developed by the bacteria.
Models involving a more complex approach of the porous medium and of matter transport are commonly used to simulate biodegradation in shallow polluted layers. The SIMUSCOP model is notably used, which allows 2D-gridding of a subsoil and calculation of the aerobic biodegradation on the BTEX, developed by the applicant, on the basis of the work described in the publication hereafter:
The softwares BIO1D, developed by the ECHOSCAN company, RT3D or PARSSIM1 (Texas University) can also be mentioned. Documentation relative to these models is available at the following Internet addresses:
A bibliography concerning the simulation of biodegradation within the framework of depollution is also available at the following address:
In most of these models, only the hydrocarbon molecules with a high solubility in water (BTEX) are considered. Oil is therefore present in the dissolved form and moves only by diffusion. Sometimes, residual oil moving by convection is also taken into account. Although the oil saturations involved are not the same as in an oil reservoir and emphasis is put on matter transport in the aquifer, the mathematical problematics is in fact applicable to reservoirs.
The equations used in all these models are of the form as follows:
In this equation, where
is an accumulation term, Vcα is a transport term,
is a reaction term of the 1st order and qαcα is a source term,
T is time,
xi is a space variable at x, y and z,
P is the number of chemical species,
V(xi,t) is the velocity field of a fluid (water),
D(xi,t) is the diffusion coefficient,
cα is the concentration of species α, and
qα is the kinetic reaction coefficient of the 1st order of species α.
The problem is completed by means of a certain number of initial conditions and of boundary conditions such as the initial concentrations, the diffusion source zones, the impossible transport zones, etc.
In order to describe a geologic porous medium, 3D models have been developed wherein an aquifer zone is gridded, and the velocity fields and the concentrations are determined in each grid cell.
All these models provide a very realistic description of the geologic medium, but they only take into account oils whose composition is not very elaborate, limited to some molecules among the most soluble ones or even to a single type hydrocarbon molecule. These models are therefore not usable per se for modeling biodegradation in reservoirs in order to obtain a description of the evolution of oil. Furthermore, for an application to geologic time scales, the problem remains the type of kinetics applied for biodegradation reactions.
The method according to the invention allows to model the progressive biodegradation of hydrocarbons trapped in an oil reservoir or trap studied, through the action of a bacterial population in an aquifer, from data relative to the reservoir studied, concerning the form and the height of the reservoir, the physical characteristics of the porous medium, the thickness of the transition zone between the hydrocarbons and the water, the composition of the hydrocarbons, of the flow of electron acceptors entering the reservoir and data relative to the bacterial population in the aquifer, in order to determine the development conditions of the reservoir.
It is characterized in that it comprises:
According to an implementation mode, the initial hydrocarbon filling rate of the reservoir when the temperature conditions prevailing in the reservoir lend themselves to biodegradation is first determined.
By taking account of the long-term effects of the biodegradation of oils in a reservoir, the method allows to obtain much more realistic assessments than with prior methods of the distribution of the hydrocarbon constituent fractions and to better select the reservoir development zones.
Other features and advantages of the method according to the invention will be clear from reading the description hereafter of non-limitative examples, with reference to the accompanying drawings wherein:
a diagrammatically shows, in a geologic trap under filling, the displacement of a water/hydrocarbon transition zone, biodegradation occurring in the transition zone which moves downwards as the field fills up, a case where all of the oil may be totally degraded,
b diagrammatically shows another situation where biodegradation occurs only after filling of the trap, in the water/hydrocarbon transition zone located at the base of the reservoir; the biodegradation <<rises>> slowly in the reservoir and affects only the basal part of the reservoir,
a, 3b diagrammatically show respectively a <<real>> porous medium and the simplified porous medium wherein, for calculation of the water/oil contact surface at the pore scale, the oil present in the pore is represented by a single sphere whose volume is in accordance with the oil saturation of the pore,
The model takes account of an oil composition comprising eight compound classes. Each compound class is associated with a stoichiometric balance and a preference factor; simulation thus allows to follow the evolution of the oil composition.
It uses a biodegradation kinetics involving bacteria attack mechanisms in the porous medium.
1.1.1 The Model
The tool for implementing the model is for example a known software platform called FLUID FOLDER, suited for fast simulation of traps, fluids and alteration phenomena: mixing, leaching, phase change, thermal cracking, etc.
In this model, we consider a trap (porous zone with a curved geometry allowing oil accumulation) that is discretized by means of a grid pattern. The fluid is biodegraded in a grid cell located near to the water/oil transition zone of the reservoir (
The quantities associated with the grid cell are:
The following quantities are associated with the porous zone:
Two possible geologic scenarios have been studied in this trap to model biodegradation:
1.1.1.1.1 The Equations Hereafter, Which Govern These Quantities in the Grid Cell, Are:
a) the material balance equations which govern the grid cell:
In these equations,
kinetic function of the first order depending on the bacterial population and corresponding to its respiration.
represents the number of bacteria required to cover the interface of a monolayer within the limits of the space available (at least 20% of free pore volume must remain).
1.1.1.1.2 The Compound Classes and Their Preference Coefficients
The compound classes selected to represent the oil are deduced from Peters and Moldowan's biodegradation advancement scales which correspond to the present state of knowledge of the preference factors, as defined in the following publication for example:
These classes are as follows, in order of attack preference:
Each compound class is assigned an absolute and relative preference coefficient.
The absolute preference coefficient is the amount (in relation to the total oil) of this consumed compound class if the bacteria are placed in a situation where they have equal access to each compound class. This coefficient expresses an attraction in the absolute of the bacteria for the various compound classes.
The relative preference coefficient of a compound class i is deduced from the absolute coefficient weighted by the compound class content.
where Xabs
1.1.1.1.3 Biochemical Kinetics
By first hypothesis, the bacteria function only under respiration conditions. This means that the growth stage of the bacterial population in terms of biodegradation and of amount of reactants involved in this growth stage is disregarded in this model. The system is brought back to a stable bacterial population at each calculation step which regenerates by itself and which, globally with the outside environment, behaves as a simple system that respires.
As mentioned above, the model also takes account of a biodegradation kinetics which is a function of the bacterial population and not only of the reactants according to Monod's law notably. The biochemical kinetics no longer depends only on the amount of reactants provided by the geologic environment. The bacterial population influences the amount of reactants involved.
In order to take this kinetics into account, the amount of electron acceptors involved in the biodegradation, which is a function of the bacterial population, is calculated. If the geologically imported amount is overabundant in relation to the maximum bacterial population, only part of this amount is effectively consumed; otherwise, it is considered to be entirely consumed. A first order type law is then applied.
Calculation of the Bacterial Population
As already mentioned, the bacteria tend to join together into biological flocs and to increase the surface area of the water/oil interface. For simplification reasons, it is assumed that these mechanisms are limited by the available volume, the porosity decreasing with the depth. One considers that the bacterial population occupies, on the scale of the droplets in the porous medium, the water/oil interface of a monolayer.
To calculate the bacterial population, the porous medium is represented by an equivalent medium that is geometrically simpler (
Nb=Interface/Ab where Ab=π.Rb2, with Rb: mean radius of a bacterium.
This number of bacteria obtained then has to be adjusted according to two criteria:
1) The remaining free pore space (once the volume occupied by the oil and the bacterial population counted) must be greater than 20%.
If the free pore space is below 20%, the population is adjusted so that the free pore space reaches 20% (20% is a “reasonable” arbitrary value allowing a certain bacteria mobility). In this case, this means that the bacterial population is not sufficient in number to cover all of the interface. Part of the molecules is then dissolved in the aquifer and it is also to the advantage of the bacteria to occupy the aquifer to catch these molecules.
2) The electron acceptor requirements of the bacteria during the time associated with the grid cell must be less than or equal to the amount of electron acceptors supplied.
If the amount of electron acceptors supplied by the aquifer is less than the amount required for the survival of all of the population compatible with the amount of hydrocarbons, the bacterial population will decrease within a very short period of time (a single generation of several hours must be sufficient in practice) so as to adjust to the amount of electron acceptors available. In this case, and in this case only, this means that, in the end, we come back to a system whose kinetics is controlled by the electron acceptor supply, and the equation balances can be written directly with a Monod type law well-known to specialists, which connects the bacterial growth rate to the amount of biomass present.
Thus, this model develops a new approach which takes account of the strategies of oil attack by the bacteria and of the bacterial population present to control the reaction kinetics.
Calculation of the Amount of Oil and of Electron Acceptors Supplied by Convection
In the model, convection is a constant-flow phenomenon for a cell of the vertical grid pattern, but it can be variable during filling of the next cell located below. Because of the geometry of the trap, if the flow remains constant during filling of several consecutive grid cells, the amount of oil and of electron acceptors in the cells will be variable.
The quantity used for the oil is the yearly volume entering the trap. This quantity is to be divided by the number of grid cells that can be arranged laterally in the transition zone, a quantity that is variable as a function of the geometry of the trap, in order to obtain the amount of oil filling a single cell at each unit of time.
In the simulations performed, the value of the reference case taken for this flow is 1.4 l/year; this allows filling of the Gaussian trap of height 100 m and width 2000 m in 100 000 years. For the electron acceptors, the quantity used is the mass of electron acceptors flowing through 1 ml water in one year in the aquifer.
In the simulations carried out for the type case, a 25 ppm/ml water electron acceptor saturation has been considered. If one considers only oxygen of molar mass 16 g/mol, this means, for an aquifer moving by 1 cm/year, a flow of 2 mg/ml water/year.
Calculation of the Amount of Electron Acceptors Diffused
The diffusion occurs vertically from the water column considered as an infinite medium of constant electron acceptor concentration to the transition zone. The diffusion creates a concentration gradient in the transition zone. To simplify, an average concentration is calculated for all of the transition zone.
Such a system is governed by Fick's law; the balance equation is thus:
where K is the diffusion coefficient and
represents the tortuosity (porosity).
The solution of this equation gives:
Calculation of the average value of concentration C gives:
Reservoir Filling Scenarios
Two scenarios are possible according to whether the accumulation of oil in the trap has occurred under favourable conditions (notably a compatible temperature) or not as regards biodegradation phenomena.
Scenario 1
In the first scenario, illustrated by
The flowchart of
Scenario 2
In the second scenario, illustrated by
As a result the biodegradation cannot spread very deep to the top of the trap, so that an often high proportion of the oil accumulated is not degraded. This is the most favourable case wanted by operators. The proposed method allows them to select the reservoir development conditions.
The flowchart of
Selecting scenario 1 or scenario 2 for processing the prospected trap requires knowledge of its formation conditions and of its displacements, which condition the filling temperature. This selection is made from the results of a simulation carried out by means of a basin model such as Temis 2 or 3D, or of a 1D model such as Genex.
Knowing the composition of the biodegraded oil, by using a conventional thermodynamic gas-oil calculation module, the density of the oil can be calculated and the API degree of the oils in the trap as a function of the depth can be deduced there from.
Validation of the Method on Real Components
The initial fluid is an oil from a South American field. This field is biodegraded and a series of samples of variable biodegradation degrees is provided. Furthermore, biodegradation has taken place in this field by successive fits and starts, the system being regularly supplied with fresh oil pulses, sometimes degraded, sometimes not. The non biodegraded oil mixes with the earlier degraded oil.
The exercise consisted in calibrating the various preference and stoichiometric coefficients. In each grid cell, the degraded oil was mixed with non degraded oil at a constant mixing rate of 25% so as to reproduce the episodes of oil without degradation. This approach allowed to reproduce the two biodegraded samples taken into account as shown in
The biodegradation model has been described in isolation using certain data obtained upstream by means of a basin model. It is clear that the software tool used to implement the method can be advantageously included as a complementary module in a basin modeling tool so as to directly get the modeling results it can provide.
Number | Date | Country | Kind |
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01 12892 | Oct 2001 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR02/03387 | 10/3/2002 | WO | 00 | 9/9/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/031644 | 4/17/2003 | WO | A |
Number | Name | Date | Kind |
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6151566 | Whiffen | Nov 2000 | A |
6766817 | deSilva | Jul 2004 | B2 |
20060020438 | Huh et al. | Jan 2006 | A1 |
Number | Date | Country | |
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20050015228 A1 | Jan 2005 | US |