BE1027945B1 - Method for modeling hydrogeological impacts - Google Patents

Abstract

The present invention relates to a method for modeling the hydrogeological impacts of events on a geographic area.

Description

Method for modeling hydrogeological impacts Hydrogeology is an interdisciplinary science which studies groundwater for applications such as the management of groundwater pollution, the management of water resources and geothermal energy. Hydrogeology deals with the distribution and circulation of groundwater in soil, rocks, taking into account their interactions with geological conditions and surface water.

The present invention relates to a method for modeling hydrogeological impacts on a geographical area, the hydrogeological impacts following events.

In general, such methods for modeling hydrogeological impacts of a geographical area of events are known from the state of the art.

Generally, this type of modeling method uses a large number of pre-existing data from a few available point observation points. These point observation points are, for example, drilling points, observation piezometers, rock outcrops, groundwater emergences, etc.

In addition, they are based on assumptions of the homogeneity of the subsoil of the geographical area, the homogeneity of the subsoil being very rarely encountered in reality and the geographical area being limited to a site on which the event occurs. at a time "t". These modeling methods therefore do not take into account the hydrogeological impacts of a geographical area of events that vary over time.

| It is therefore important to understand and predict the behavior of groundwater in time and space under the effect of anthropogenic or environmental events interacting with soil, groundwater and surface water by providing a reliable and robust tool to understand and predict hydrogeological impacts using observation points at the scale of a geographical area according to the events to be taken into account or to be predicted.

By the terms anthropogenic events, one understands according to the present invention, an underground water catchment, a deepening of quarries under the water table, a contamination, a construction of buildings with foundation in the water table, a waterproofing of the grounds, a drainage / a artificial recharge, groundwater geothermal energy, regional lowering of the groundwater level following an overexploitation of groundwater, etc.

By the terms environmental events, one understands according to the present invention, intense and / or extreme rainfall phenomena, droughts, modifications via climatic changes such as for example floods, landslides, etc.

The aim of the invention is to overcome the drawbacks of the state of the art by providing a method for modeling hydrogeological impacts on a geographical area of events comprising the steps of: a) determining the boundaries of said geographical area; b) Acquisition of pre-existing data from said geographical area; c) Development of a first model at least on the basis of pre-existing data and setting of conditions at said borders of said geographical area;

d) Adjustment of said first model by the conditions at said boundaries with obtaining a first adjusted model; e) Collection of additional data based on field measurements on a geographic site; fl Calilorage of said first model adjusted using additional data on said geographic site with obtaining a robust predictive model of said geographic area; g) Simulation of said hydrogeological impacts on said geographical area of events by introducing parameters characteristic of said events into said robust predictive model, including the isolation of uncertain impacts and obtaining a visualization of said hydrogeological impacts of said events.

As can be seen, a method of modeling hydrogeological impacts on a geographical area of events according to the present invention comprises a step of determining the boundaries of said geographical area. This step makes it possible to frame the geographical area in which the hydrogeological impacts of events take place, which may or may not occur in the geographical area. By defining a perimeter based on events, the area of influence is determined.

Generally, said geographical area is different from said geographical site, for example, said geographical area can be much wider than said geographical site, such as 3, 4, 5, or even 20 to 100 times wider. This is particularly useful when the conditions at the borders of said geographical area are fixed and must not influence the results at the geographical site.

For the purposes of the present invention, said events having a hydrogeological impact on said geographical area and / or said geographical site are, for example, groundwater pollution, industrial discharge, construction of a dam, construction of an underground car park, construction. storm basin, underground water capiage, deepening of quarries under the water table, contamination, construction of buildings with foundation in the water table, soil waterproofing, artificial drainage / recharge, geothermal energy on the water table, regional lowering of the water level water table following overexploitation, etc. which occur either in the geographical area or in said geographical site or else in the vicinity of said geographical area or said geographical site. Within the meaning of the present invention, the impacts can thus be reliably identified beforehand, by example to obtain an operating permit, events that may occur.

For example, depending on the case, the method according to the invention makes it possible to secure the underground water resource and its production, to exploit it in a sustainable, optimized and environmentally friendly way by modeling the hydrogeological impacts of events such as quarry projects, underground works, catchments, batteries of water catchment wells, definition of protection perimeters of drinking water catchments; to locate, understand, contain and effectively clean up the hydrogeological impacts of events such as groundwater pollution; to anticipate the problems of groundwater pollution migration; to minimize the impacts in terms of groundwater drawdown, soil compaction, drying up of springs and streams, to model a geothermal system on groundwater (production of hot, cold and storage).

By the terms works, is meant according to the present invention, wells, catchments or piezometers available.

The pre-existing data are for example cartographic data such as plans, topographical, geotechnical, geological, pedological, hydrogeological or cross-sectional maps.

The pre-existing data are also, for example, hydrogeological data such as field test results, piezometry, flow, chemical analyzes of groundwater, etc. Within the meaning of the present invention, said boundary conditions are for example the position of the hydrogeological peaks. , the position of topographic ridges, the position of major watercourses such as for example the height, the flow and the rate of infiltration of the watercourse in the water table, the flow rate and the rate of drainage of the water table by the watercourses, the position of springs, boundaries of poorly permeable geological formations, water flows across geological boundaries, etc.

The method of modeling hydrogeological impacts on a geographical area of events according to the present invention comprises a step of acquiring pre-existing data from said geographical area. This step makes it possible to control the site from a point of view of the hydrogeology of the geographical area and to effectively integrate into the hydrogeological model the reality of the field, of the hydrogeological context, for example the heterogeneity of the subsoil. . This step of acquiring pre-existing data also makes it possible to identify natural interactions such as interactions between the water table and the surface water network, rainfall recharge (for example, infiltration (or drainage) of a water course. water to / from the water table, reaction of water tables to a rainfall event, influence of karst conduits, influence of the different types of geological formations present) and a potential future need for planning of field measurements.

This modeling method according to the present invention comprises a step of developing a first model at least on the basis of pre-existing data.

This step allows an identification / interpretation and mathematical integration of the aquifers present (including extent, depth, height), a preparation of a finite element grid, a setting of the conditions at the internal and external borders of the geographical area.

This makes it possible to obtain a first model physically based and digitally transposed: the data are represented in the form of a 3D finite element digital model and mathematically constrained by the predefined boundary conditions.

Advantageously, an adjusted model is then obtained and this first adjusted model is obtained by creating a two-dimensional triangular finite element mesh, transposing the two-dimensional trangular finite element mesh into a three-dimensional hydrogeological model multilayer which represents said first fitted model.

This transposition allows reliable reproduction of the geology in said geographical area as well as the parametrization of said first adjusted model and the validation of the stability of said first adjusted model by the adjustment of the geometry or of the pre-existing data.

It is therefore important to carry out a collection of additional data on the basis of field measurements on a geographical site in order to allow the characterization of said geographical site.

This makes it possible to supplement the pre-existing data with additional data essential to allow the calibration of said first adjusted model using additional data on said geographical site with obtaining a robust predictive model of said geographical area. The calibration is carried out by adapting the parameterization of said first adjusted model so that the latter can reproduce said events and reliably predict said impacts. The calibration is carried out on the basis of at least one of the following regimes: in steady state, in transient regime in underground flow, in mass transport or in heat transport. This makes it possible to understand said hydrogeological impacts on a geographical area of events in order to strengthen and make said first adjusted model more reliable, with obtaining a robust predictive model of said geographical area.

By steady state is meant a static regime according to the present invention. By transient regime is meant a dynamic regime according to the present invention.

The regime on which the calibration is operated depends on the data available and depends on the objectives sought by the model. The more the calibration is carried out over a large number of speeds, the more reliable and robust it is.

The step of simulating said hydrogeological impacts on said geographic area of events makes it possible to take into account the improvements identified in the previous step by introducing parameters characteristic of said events into said robust predictive model, including the isolation of uncertain impacts and obtaining a visualization of said hydrogeological impacts of said events. This makes it possible to respond to all the constraints dependent on the events defined as a function of the problem to be solved.

For example, it is important to secure the groundwater resource as well as its production and to allow its exploitation in a sustainable, optimized and environmentally friendly way. In addition, it is important to locate, understand, contain and effectively clean up groundwater pollution; to anticipate the problems of groundwater pollution migration; to minimize the impacts in terms of groundwater drawdown, soil compaction, drying up of springs and streams; to be able to model a geothermal system and the dissipation of an energy plume.

The modeling method according to the present invention comprises an additional step of evaluating the sensitivity of the robust predictive model of said geographical area by comparing the calculated influence of a series of parameters with the measured influence of the same series of parameters. . This step makes it possible to control the results of the simulations to be carried out according to the events as well as to evaluate the uncertainty and the avenues for improvement of the robust predictive model obtained in the previous step.

The purpose of the step of evaluating the sensitivity of the robust predictive model according to the present invention consists in evaluating the imprecision which accompanies the results of the model and, where appropriate, it allows the identification of improvements. This step also allows the identification of strategic parameters.

In a preferred embodiment, the modeling method according to the invention comprises an additional step which is the evaluation of the sensitivity of the robust predictive model of said geographical area by comparison of the calculated influence of a series of parameters with l 'measured influence of the same set of parameters; Preferably, said hydrogeological impacts according to the present invention are chosen from the group comprising the modification or the simulated situation of the water level in groundwater and surface water, the modification or the simulated situation of the temperature of the groundwater and water. surface, the modification or the simulated situation of the electrical conductivity in wells and the structures, the modification or the simulated situation of the flow of a watercourse, the modification or the simulated situation of the flow of springs, quarries, the modification or simulated situation of the extent of a pollution, the modification or simulated situation of the depth of a position, the modification or the simulated situation of the pollution migration speed, the modification or the simulated situation of the speed of migration of a heat plume, Said hydrogeological impacts are obtained by various field measurement techniques carried out in said e geographical area such as a piezometer or pumping well drilling, a synchronous piezometric campaign, automatic piezometric monitoring, test pumping, chemical sampling and analyzes, surface water gauging, a fluorescent tracing test or A heat tracing test.

By the terms piezometric campaign, one understands according to the present invention, a realization of measurements of water levels in the works and the creation of a cartography of the piezometry determine the direction and the gradient of the underground flows at an instant "it". .

By the terms automatic piezometric monitoring, is meant according to the present invention, a network of automatic monitoring probes making it possible to continuously monitor the evolution of the height and the temperature of the water table or of the electrical conductivity in the wells and piezometers. deemed relevant.

By the terms test pumping is meant according to the present invention, a test pumping step by step, each step being carried out until the water level stabilizes, a long-term test pumping in which the start pumping is kept constant for several consecutive days.

Sampling of wells and piezometers and chemical analyzes provide a snapshot of the state of groundwater contamination at a number of measurement points.

By the terms of gauging the surface water network, is meant according to the present invention, the performance of flow measurements in the surface water included in said geographical area in order to estimate the interaction with the groundwater. In fact, the gauging of the surface water network allows the evaluation of the potential for drainage or infiltration of groundwater by surface water, verification of the phenomena of losses or infiltration.

By the terms fluorescent tracing, is meant according to the present invention, the injection of tracers into the wells and in the case of restitution of the tracer (s), the monitoring of the spectrofluorometry downstream in other wells, in other sources.

By the terms thermal tracing test, is meant according to the present invention, the heating of the underground water and the injection of this underground water into a well by monitoring the evolution of the temperature in the structures.

Advantageously, said events on a geographical site according to the present invention are chosen from the group comprising a collection or release of water, an industrial discharge, a deviation of a watercourse, a pollution of groundwater, a contamination, soil waterproofing, drainage, artificial recharge, construction, exploitation of a natural surface or underground resource, temperature variation, regional lowering of the water table following overexploitation, quarry projects , underground works projects, water collection well battery projects, definition of the protection perimeter of drinking water catchments, nape drawdown, soil compaction, spring and stream drying up.

The collection or release of water can intervene, for example, in the modeling of a geothermal system dependent on an underground water table.

The pollution can come, for example, from an IO company releasing toxic products into the water or from a transport accident causing the pollution of a geographical site by the flow of a fuel such as kerosene.

By the terms construction is understood according to the present invention a parking lot, a storm basin, a dam, the construction of a building with a groundwater foundation, the construction of a geothermal system on a groundwater, deepening of quarries under the groundwater. aquifer or any other man-made construction that may have an effect on soils, subsoils, surface water and groundwater.

Preferably, said geographical site according to the present invention is identical or different from said geographical zone such as for example remote or included from said geographical zone.

Indeed, said geographic site is for example included in said geographic area, the perimeter of said geographic site being less than or equal to the defined perimeter of said geographic area depending on the events to be taken into account. It is possible that the event only requires a small area of land but that the consequences of another fortuitous event taking place outside of said geographical site but still present in the geographical area have consequences on said geographical site. Advantageously, said boundary conditions according to the present invention are chosen from the basic group of measurements made up of the position of hydrogeological ridges, the position of topographic ridges, the position of major watercourses such as, for example, the height, the flow rate and rate of infiltration of the watercourse in the water table, flow rate and rate of drainage of the water table by the watercourse, the position of sources, limits of low permeability geological formations, limit of geological formation low permeability, interactions of groundwater with the hydrographic network or the drainage network, the average piezometric situation, low water or high water reproduced in steady state or piezometric evolution monitored and reproduced in transient regime.

The determination of said conditions at the appropriate borders makes it possible to obtain a first physically based model.

Advantageously, said series of parameters according to the present invention is chosen from the group consisting of the hydraulic conductivity of the soils, the infiltration or the boundary conditions.

The hydraulic conductivity is preferably deduced from test pumpings or from bibliographic data associated with the nature of the geological layers.

The infiltration is preferably calculated on the basis of meteorological precipitation, the nature of the soil, the coating, the slopes.

The border conditions are obtained on the basis of piezometric maps, piezometric measurements, hydrogeological and geological maps.

Said series of parameters makes it possible to evaluate the sensitivity of the first robust predictive model to different events by varying these parameters and by observing the variation in hydrogeological impacts.

Using said series of parameters, it is possible to carry out simulations with sets of measured and calculated parameters, which makes it possible to validate or not the results obtained during the calibration.

In a preferred embodiment, said pre-existing data according to the present invention are chosen from the group consisting of data at the scale of said geographical site and data at the scale of the geographical area, or of hydrogeological characteristic measurements of said geographical area. .

By the terms given at the scale of said geographical site according to the present invention, is meant for example cartographic data such as plans, topographical, geotechnical, geological, pedological, hydrogeological, cross-sectional maps, hydrogeological data such as the results of tests. field, piezometry, flow, chemical analyzes of groundwater, historical data, etc.

By the terms given on the scale of said geographical area, is meant according to the present invention, for example existing technical data, additional payload data.

By the terms hydrogeological characteristic measurements, is meant according to the present invention, the field measurements carried out in said geographical area such as a piezometric or pumping well drilling, a synchronous piezometric campaign, an automatic piezometric monitoring, a test pumping. , sampling and chemical analyzes, A gauging of the surface water network, a fluorescent tracing test or a thermal tracing test.

In a particularly preferred embodiment, said additional data according to the present invention are chosen from the group consisting of hydrogeological characteristic measurements of said geographical area.

Said measurements = hydrogeological characteristics make it possible to obtain data essential for the characterization of the wells, for the calibration of the first model adjusted, in flow, in IO transport.

The flow caliorage makes it possible to obtain a reproduction of static or dynamic piezometric situations and to integrate the interaction of groundwater or surface water in said first fitted model of said first fitted model.

The caliorage in transport makes it possible to have a photograph of the molecules sought,, to characterize the transport of pollutants, to characterize the transport of heat.

Advantageously, said sensitivity of the model according to the present invention is calculated by parameters chosen from the group of hydraulic conductivity of soils and permeabilities, infiltration or said boundary conditions.

In a preferred embodiment, the modeling method according to the present invention further comprises a 3D printing of said robust predictive model and / or of said impocted model.

Other embodiments of the modeling method according to the invention are indicated in the appended claims.

Other characteristics, details and advantages of the invention will emerge from the description given below, without limitation and with reference to the drawings and to the examples.

The subject of the invention is also a model as a product implemented by a computer, obtained by the modeling method according to the invention.

Other embodiments of the model as a computer-implemented product obtained by the modeling method according to the invention are indicated in the appended claims.

Other characteristics, details and advantages of the invention will emerge from the description given below, without limitation and with reference to the drawings and to the examples.

Another subject of the invention is a computer program comprising instructions configured to execute the steps of the modeling method according to the invention.

Other embodiments of the computer program comprising instructions configured to perform the steps of the modeling method according to the invention are indicated in the appended claims.

Other characteristics, details and advantages of the invention will emerge from the description given below, without limitation and with reference to the drawings and to the examples.

Another subject of the invention is a computer program comprising instructions configured to execute the steps of the modeling method according to the invention.

Other embodiments of the computer program comprising instructions configured to perform the steps of the modeling method according to the invention are indicated in the appended claims.

Other characteristics, details and advantages of the invention will emerge from the description given below, without limitation and with reference to the drawings and to the examples.

The subject of the invention is also a computer program as a product storing instructions configured to execute the steps of the modeling method according to the invention.

Other embodiments of the computer program as an instruction storing product configured to perform the steps of the modeling method according to the invention are indicated in the appended claims.

Other characteristics, details and advantages of the invention will emerge from the description given below, without limitation and with reference to the drawings and to the examples.

The subject of the invention is also a device configured to execute the steps of the modeling method according to the invention.

Other embodiments of the device configured to perform the steps of the modeling method according to the invention are indicated in the appended claims.

Other characteristics, details and advantages of the invention will emerge from the description given below, without limitation and with reference to the drawings and to the examples.

In the drawings, Figure 1 is a graph which illustrates the flow rate and water level of a watercourse included in a section of said geographic area.

Figure 2 is a representation of a 3D hydrogeological model of the defined geographic area.

Figure 3 is a graph which illustrates the sensitivity of the hydrogeological model by comparing the measured absolute piezometry versus the simulated absolute piezometry.

Figures 40, 4b and 4c each show a plan view and a sectional view which illustrate the spread of contamination due to an accident after 1 day, after 30 days and after 250 days.

In the figures, identical or similar elements bear the same references Examples - Aircraft accident and renewal of the aerodrome permit.

We have developed. an impacted hydrogeological model according to the present invention for evaluating the hydrogeological impacts on the determined geographical area, said hydrogeological impacts being due to ONE aircraft accident and also with a view to renewing the aerodrome permit.

According to the present invention, the borders of said geographical area have been demarcated at the region of Spa. Bibliographic data was collected in the Spa region to allow the development of a first hydrogeological model based on pre-existing data. This first hydrogeological model made it possible to fix the conditions at the borders of the geographical area.

Additional data were then measured to characterize the geographic site and improve the first hydrogeological model using piezometric and gauging campaigns shown in Figure 1. These piezometric campaigns illustrate the water level reading in the wells of the zone (not shown). The gauging campaigns represent the measurement of flow and news of streams and rivers. FIG. 1 represents the speed in cm / s of said watercourse as a function of the depth in cm and of the width in cm of said watercourse. In Figure 1, we can see that the width of the impacted stream is 4 m and that the depth of said stream is about 25cm. We can also see that the speed of the stream varies according to the depth and width of the stream. The speed is zero or almost zero near the watercourse and it is highest between 0.5 m and 1 M in width and between 5 and 15 cm in depth and the highest between 1 m and 1.5 m in width and between 5 and 15 cm deep. These additional measures made it possible to correct, refine and adapt the first model based on pre-existing data to the realities of the geographic site. We obtain the first hydrogeological model which is visualized in 3 dimensions such as, for example, the hydrogeological model in figure 2.

FIG. 2 illustrates the geographical area of Spa comprising different geological layers of the subsoil and a series of minor and major watercourses on the basis of data which have been calculated and measured on the geographical site and the geographical area.

Then, this hydrogeological model was calibrated by modifying the parameters so that the model is able to reproduce the additional data obtained by the measurements over the geographical area with obtaining a robust predictive model.

We analyze the sensitivity of the fitted robust predictive model which is validated by the reproduction of the water levels of the aquifer in FIG. 3 comparing the absolute piezometry measured with respect to the simulated absolute piezometry. We obtain a perfect straight line at 45 °.

The fitted robust predictive model is used to predict the consequences of an aircraft accident in Figures 4a, 4b, 4c.

Several “worst-case” scenarios have been identified and simulated by the robust hydrogeological predictive model. These worst-cases were the accumulation of unfavorable events such as an accident 4 of two larger planes taking off from the aerodrome in a particularly difficult access area and where the conditions of oil infiltration into the ground were the most. favorable.

Figures 4a, 4b and 4c represent the results in terms of pollutant propagation speed, contaminated water volume and direction of pollutant movement were presented and analyzed for these different scenarios. Figure 4a shows a plan view 1 at the level of the contamination core and a sectional view 2, 1 day after the accident 4. The direction of the flow 3 of the pollution is indicated. The effect of setting up emergency solutions such as containment wells 5 was measured. The containment wells 5 are, on day 1, inactive because they have not yet been reached by the propagation of the pollution.

Figure 4b shows a plan view 1 at the level of the contamination core and a sectional view 2 on day 30 after the accident 4 and on the last day before the start of pumping. The direction of flow 3 of the pollution is indicated. The effect of setting up emergency solutions such as containment wells 5 was measured. The containment wells 5 are, 30 days after the accident 4, inactive because they have not yet been reached by the spread of pollution.

FIG. 4 c represents a plan view 1 at the level of the contamination core and a sectional view 2, 250 days after the accident 4 when the pumping operations are carried out. The direction of flow 3 of the pollution is indicated. The effect of setting up emergency solutions such as containment wells 5 was measured. Containment wells 5 have been active since the start of pumping.

A flowchart identifying the main means of intervention or management in the event of an aircraft accident was finally established and presented in Figure 4.

It is understood that the present invention is in no way limited to the embodiments described above and that many modifications can be made thereto without departing from the scope of the appended claims.

Claims (18)

1. Method of modeling hydrogeological impacts on a geographical area of events comprising the steps of: a) Determination of the boundaries of said geographical area; b) Acquisition of pre-existing data from said geographical area; c) Development of a first model at least on the basis of pre-existing data and setting of conditions at said borders of said geographical area; d) Adjustment of said first model by the conditions at said boundaries with obtaining a first adjusted model; e) Collection of additional data based on field measurements on a geographic site; f) Calilorage of said first model adjusted using additional data on said geographic site with obtaining a robust predictive model of said geographic area; g) Simulation of said hydrogeological impacts on said geographical area of events by introducing parameters characteristic of said events into said robust predictive model, including the isolation of uncertain impacts and obtaining simulation results allowing visualization of the hydrogeological impacts of said events associated with the answers to the questions asked at the start of the process. 2. Modeling method according to claim 1, comprising an additional step of evaluating the sensitivity of the robust predictive model of said geographical area by comparing the calculated influence of a series of parameters with the measured influence of the same series. parameters; 3. Modeling method according to claim 1 or 2, wherein said hydrogeological impacts are selected from the group comprising the modification or the simulated situation of the water level in groundwater and surface water, the modification or the simulated situation. the temperature of groundwater and surface water, the modification or simulated situation of the electrical conductivity in wells and structures, the modification or simulated situation of the flow of a watercourse, the modification or the simulated situation the flow of sources, quarries, the modification or the simulated situation of the extent of a pollution, the modification or the simulated situation of the depth of a position, the modification or the simulated situation of the speed of migration of the pollution, the modification or simulated situation of the migration speed of a heat plume. 4. Modeling method according to any one of the preceding claims, in which said events on a geographical site are chosen from the group comprising a collection or release of water, an industrial discharge, a deviation of a watercourse. , groundwater pollution, contamination, soil waterproofing, UN drainage, artificial recharge, construction, exploitation of a natural surface or underground resource, temperature variation, regional lowering of the water table following overexploitation, quarry projects, underground works projects, water collection well battery projects, definition of the protection perimeter of drinking water catchments, nape drawdown, soil compaction, drying up of springs and streams. 5. A modeling method according to any one of the preceding claims, in which said geographic site is identical to or different from said geographic area, for example remote from or included in said geographic area. 6. Modeling method according to any one of the preceding claims, in which said boundary conditions are chosen from the group consisting of the position of the hydrogeological ridges, the position of the topographic ridges, the position of the major watercourses such as for example. the height, flow and rate of infiltration of the watercourse in the water table, the flow rate and the rate of drainage in the water table by the watercourse, the position of the sources of the limits of low permeable geological formations, the water flows across geological limits, interactions of groundwater with the hydrographic network or the drainage network, the average piezometric situation, low water or high water reproduced in steady state or piezometric evolution monitored and reproduced in regime transient. 7. A modeling method according to any one of the preceding claims, in which said series of parameters are chosen from the group consisting of the hydraulic conductivity of the soils and the infiltration or the boundary conditions. 8. Modeling method according to any one of the claims, in which said pre-existing data are chosen from the group consisting of data at the scale of said geographical site, data at the scale of the geographical area, or hydrogeological characteristic measurements. of said geographical area. 9. A modeling method according to any one of the preceding claims, in which said additional data are chosen from the group consisting of the hydrogeological characteristic measurements of said geographical area. 10. A modeling method according to any one of claims 2 to 9 when they depend on claim 2, in which said sensitivity of the model is calculated by parameters, in which said sensitivity of the model is calculated by parameters chosen from the group of hydraulic conductivity of soils and permeabilities, infiltration or said boundary conditions. 11. A modeling method according to any one of the preceding claims, further comprising a 3D printing of said robust predictive model and / or of said impacted model. 12. A modeling method according to any one of the preceding claims, in which said events are anthropogenic events. 13. A modeling method according to any one of the preceding claims, in which said events are events on the geographic site. 14. The modeling method according to claim 13, wherein said geographic area is larger than said geographic site. 15. Model as a product implemented by a computer, obtained by the method according to any one of claims 1 to 14. 16. A computer program comprising instructions configured to execute the steps of the modeling method according to any one of claims 1 to 14, when executed as a processor. 17. A computer program as a product storing instructions configured to perform the steps of the modeling method according to any one of claims 1 to 14, when executed as a processor. 18. Device configured to execute the steps of the modeling method according to any one of claims 1 to 14.