IT201800007040A1 - FITTING WELLS FOR ELECTRICAL TOMOGRAPHY INVESTIGATIONS - Google Patents

Description

FITTING WELLS FOR TOMOGRAPHY INVESTIGATIONS

ELECTRIC

DESCRIPTION

The present invention relates to insertion wells for electrical tomography investigations. The invention also refers to an apparatus for electrical micro tomography which includes a plurality of the aforementioned wells in the context of plant physiology and a method of monitoring the sucking activity of a plant through the aforementioned apparatus.

In the field of plant physiology it is known to use three-dimensional electrical micro tomography techniques (Micro-ERT 3D) of the subsoil for precision agriculture purposes,

This investigation technique falls within the scope of direct current resistivity methods and is based on the use of artificial sources to introduce an electric current into the ground and measure the resulting potential difference. Typically, in such applications, current is introduced through two electrodes, essentially consisting of two metal stakes driven into the ground, and the potential difference is measured through two other electrodes, using Ohm's law. In this way it is possible to determine the spatial distribution of resistivities in the investigated soil.

This principle is used in Electrical Resistivity Tomography (ERT) to calculate the distribution of subsurface resistivity using a large number of measurements made by the electrodes.

One of the most interesting applications of micro-ERT techniques, ie tomographic investigations of electrical resistivity carried out on very small scales, is represented by the analysis of the root systems of plants, thanks to the high level of detail that they allow to obtain.

The Micro-ERT 3D analyzes are in fact able to precisely characterize the humidity conditions of the subsoil and monitor the distribution of the sucking areas relating to the activities of the plant's roots.

In order to be able to place a sufficiently high number of electrodes in a precise and at the same time simple manner, these can be grouped in wells, ie in support structures which are inserted into the ground in correspondence with the area to be analyzed. An example of a micro-ERT well is described in Boaga J,, Rossi M ,, Cassiani G ,, Monitoring Soil-plant Interactions in an Apple Orchard Using 3D Electrical Resistivity Tomography Procedia Environmental Sciences Volume 19, 2013, Pages 394-402. In particular, this document describes a micro ERT analysis configuration for plant physiology in which four wells are used located at the vertices of the square that identifies the area to be characterized.

One of the problems encountered by the inventor of the present invention relates to a lack of electrical contact between the electrodes of the wells and the ground, which is necessary for a good quality of the measurement.

An improvement in the quality of the measurement could in fact be desirable in the agricultural sector, in which Micro-.ERT techniques could be exploited to optimize plant irrigation techniques thanks to the characterization of the plant's sucking areas.

To date, in fact, the monitoring of the evolution of the water content in the subsoil and of the related root activity typically takes place through direct and invasive ways. To date, however, the common electrical micro tomography has been applied only for years as a non-invasive geophysical analysis for the study of the root zone. However, the use of surface electrodes alone does not allow a detailed and accurate three-dimensional description of the first subsoil affected by root activity.

Therefore, the problem underlying the present invention is that of providing a shaft with insertion for electrical tomography investigations that is structurally and functionally conceived to overcome one or more of the drawbacks complained of with reference to the cited prior art.

A further purpose is to provide a piling well that allows to improve the quality of the resistivity measurements carried out within the ERT techniques compared to known solutions.

It is also an object of the present invention to improve the electrical contact between the electrodes of the pit and the ground.

Another purpose of the present invention is to provide a sump that allows to create an apparatus for micro-ERT that allows to monitor the evolution in space and time of the water content of the subsoil and its root activity.

This problem is solved and these purposes are achieved by the invention by means of a well for electric tomography investigations made in accordance with claim 1.

In fact, it will be appreciated that the presence of fins protruding outwards with respect to the elongated support to which the electrodes are fixed allows for improved coupling with the ground, ensuring high measurement accuracy.

In addition, the sump of the present invention allows to obtain a resolution sufficient in order to monitor the evolution in space and time of the water content of the subsoil and the relative root activity of the plant in order to optimize the irrigation resource. This advantageously allows you to create new perspectives for on-site and non-invasive monitoring of the root system and its evolutions, allowing you to complete the usual underground monitoring that monitor the activity status of the plant above the surface.

According to a preferred embodiment, the well comprises a common conductor which extends along the elongated support to supply current to the electrode (s) or sense the potential difference across them. This characteristic advantageously allows to simplify the structure of the manhole and in particular of the electrical components.

In one embodiment, the support has an internal cavity, within which the common conductor extends so as to avoid contact with the ground and thus avoid possible damage during insertion.

According to a preferred embodiment, the fins develop in a direction parallel to the longitudinal development direction of said elongated support and, preferably, they extend towards the end destined to remain on the surface. These characteristics allow to avoid that the presence of the fins excessively obstructs the insertion of the well while offering the optimal contact that the present invention allows to obtain.

According to a preferred embodiment, the end of the elongated support has a tapered shape. In this way, the pit is easy to install by percussion or thrust or possibly through a small pre-hole that can be made with common hand probes.

Further preferred features are defined by the dependent claims.

According to a further aspect, the invention also refers to an apparatus according to claim 10.

The apparatus for micro tomography of the present invention allows to insert non-invasive instrumented micro-wells around individual plants allowing, thanks to modern multi-channel geoelectric acquisition systems, to monitor with high details the space-time evolution of the electrical characteristics of the volume. of interest. In fact, thanks to the presence of the protruding fins, it is possible to obtain a measurement accuracy that allows to obtain the resolution required for applications in the field of plant physiology.

Based on yet another aspect, the invention also refers to a method of monitoring the sucking activity of a plant. This method provides for obtaining a plurality of resistivity data representative of the characteristics of the soil at different instants by means of a micro tomography apparatus according to the present invention, relating the data obtained to the water content in the areas adjacent to the root system of the plant, determining a distribution of irrigation water in the subsoil as a function of time and determining the sucking activity of the plant on the basis of this distribution.

The characteristics and advantages of the invention will become clearer from the detailed description of some of its illustrated embodiments, by way of non-limiting example, with reference to the accompanying drawings in which:

Figures 1 A and 1 B are side views of a pivot well for electrical tomography investigations according to the present invention in two respective operating configurations; And

Figure 2 is a schematic illustration, according to a perspective view of an apparatus comprising a plurality of wells made in accordance with the present invention in a monitoring configuration of a plant.

With initial reference to Figure 1, a piling well for electrical tomography investigations of a ground G is indicated as a whole with the reference number 100.

It will be understood that in the context of the present invention the term well, sometimes also indicated in the reference technical sector also with the English term drillhole, will refer to a device having one or more electrodes suitable for being driven into the ground to allow investigation activities. using electrical tomography systems. The well 100 of the present invention comprises an elongated support 1, made of insulating material and insertable in the ground (G) in correspondence with a survey area.

In an example of application, schematized in Figure 2, the survey area is represented by the area adjacent to the root system of a plant P and, as will be seen in greater detail below, in this case a series of wells 100 are placed around to plan P, preferably at the vertices of the survey area. In this configuration, the wells of the present invention allow to perform detailed 3D electrical tomographies of the first subsoil where the plant apparatuses exist.

Preferably, the elongated support 1 of the well is made of PVC. According to a preferred embodiment, the elongated support 1 has a tubular shape, with a cavity 10 extending longitudinally inside it.

In one embodiment, the elongated support has a tapered end 12, intended to be fixed in the ground. An opposite head end 11 of the elongated support 1 is instead intended to remain close to the surface of the ground G during the investigation.

According to a preferred embodiment, the tapered end 12 is made of Teflon, in particular at one of its points. The elongated support 1 can also comprise an upper closing element 13, possibly also made of Teflon, to facilitate its insertion with a small striking mass.

With reference again to Figure 1, the wells 100 also comprise one or more electrodes 2 located at a distance from the head end 11 of the elongated support 1.

In one embodiment there are a plurality of electrodes, for example 12 in the example shown in Figure 2, preferably equidistant from each other along the longitudinal direction of the support 1. The electrodes 2 are made of an electrical conductive material which can be advantageously represented by stainless steel so as to be able to resist better when driven into the subsoil.

Preferably, the electrodes 2 comprise a band 20 that surrounds the support element 1, embracing the extrados of the elongated element.

As can be appreciated from Figures 1 A and 1 B, the electrodes 1 of the well 100 comprise a plurality of fins 21 projecting outwards with respect to the elongated support 1, as in the configuration of Figure 1 B, or which can project towards the external as in the configuration of figure 1 A.

The fins 21 are also made of electrical conductive material and also contribute to the introduction of electric current into the ground and to the detection of the electronic potential thus generated.

It will in fact be appreciated that the fins 21 are also stuck in the ground during the use of the well 100.

However, the provision of outwardly projecting fins allows to reach areas not immediately adjacent to the elongated support 1, areas where the contact between electrodes 2 and the ground G may not be optimal since the latter has been stressed by the driving action of the wells.

Preferably, the fins 21 extend from the band 20 in a direction parallel to the longitudinal development direction X of the elongated support 1.

In a preferred embodiment, the tabs 21 extend from the band 20 in the direction of the head end 11.

In some embodiments, the fins 21 are connected to the band 20 by a deformable connection.

This last feature allows you to open the fins, once placed on the elongated element adjacent to its external surface, before driving the well into the ground. This allows an excellent electrode-ground coupling without compromising the ease of driving with a shrewdness of easy execution and economic realization.

Always referring to Figures 1 A and 1 B, the electrical connection is advantageously made by means of a conductor 3 which extends along the elongated support 1. Preferably the conductor 3 extends along the internal cavity 10 defined in the elongated support as previously illustrated. This allows to facilitate the insertion of the well, favoring the maximum electrical coupling between the electrodes and the ground and favoring the watertightness of the well. For this purpose, the conductors 3 can exit through a side outlet made in the head of the well.

The conductors 3 therefore allow to supply current to the electrodes 2 or to detect the potential difference across them.

Figure 2 illustrates an example of application of the wells 100 in an apparatus for electrical micro tomography.

The apparatus also includes a resistivity meter to which the wells are connected via the conductors 3.

According to a preferred embodiment, the apparatus comprises 2 or 4 wells 100 fixed to the ground and, preferably, some surface electrodes 4 in order to delimit the three-dimensional volume under investigation. The surface electrodes 4 can also be advantageously made of stainless steel, for example by means of stainless steel bars. By way of example, the bars can be 10cm in length and 3m in diameter with a turned tip. The surface electrodes 4 are electrically connected to the multichannel resistivity meter by means of electrical cables.

In the example of Figure 2, 4 wells were fixed to the ground, each equipped with 12 electrodes, with 24 additional surface electrodes for a total of 72 electrodes in simultaneous acquisition.

As mentioned above, the electrical connection can be made by making the conductors 3 come out from the side exit of the well head, preferably using a tubular, for example a corrugated, tin containing the same.

At a suitable distance from the head of the pit, the tubular ends with a watertight box containing the terminals corresponding to the individual conductors. Each connection terminal can advantageously be numbered univocally to allow the correct connection to any multi-channel geo-resistivity meter.

In one embodiment, the head of the well, which typically comes out of the ground for a few centimeters once fixed, is equipped with a belt, or other gripping element, designed to facilitate its extraction if necessary.

It will also be appreciated that the apparatus according to the present invention makes it possible to make available an innovative method of monitoring the sucking activity of a plant.

In a preferred embodiment, the method provides for the insertion of the wells 100 and the insertion of the surface electrodes 4 around the plant P, in order to delimit a three-dimensional volume under investigation. In the example shown in Figure 2, this volume is represented by 1.7 m <3> around the single plant P.

The method therefore provides for obtaining a plurality of resistivity data representative of the characteristics of the soil at different times through the tomography apparatus thus configured.

The data obtained can thus be related to the water content in the areas adjacent to the root system of the plant, so as to determine a distribution of irrigation water in the subsoil as a function of time.

The knowledge of this distribution therefore allows to determine the sucking activity of the plant.

It will therefore be appreciated that the wells of the present invention allow the three-dimensional electrical micro-tomographic monitoring of the volume affected by the root activity of the plant, allowing the estimation of the water contents in the subsoil and the study of plant sucking processes for optimization. of the use of irrigation resources, solving the age-old problem of electrode-soil contact well known in literature.

The numerous electrodes fixed around the root system make it possible to obtain very detailed tomographic images (centimeter resolution) of the subsoil and of the space-time evolutionary characteristics of the water content and of the radical suction activity. Further advantages are represented by the fact that the proposed apparatus is watertight and stainless and can be left on site for long periods allowing the operator to operate accurate time-lapse monitoring, otherwise severely limited by the non-homogeneous acquisition conditions.

Claims (10)

CLAIMS 1. Drive well (100) for electrical tomography investigations of a ground (G) comprising an elongated support (1), made of insulating material and insertable in the ground in correspondence with a survey area, one or more electrodes (2) placed spaced from a head end (11) of said elongated support (1) intended to remain close to the surface of the ground (G) during the investigation, characterized in that said electrode (s) comprise a plurality of fins (21) protruding outwards or which can protrude outwards with respect to said elongated support (1), said fins (21) being made of electrical conductive material. 2. Pivoting well (100) according to claim 1, comprising one or more common electrical conductors (3) extending / extending along the elongated support (1) to supply current to the electrode (s) (2) or detect the potential difference across them, said elongated support (1) having an internal cavity (10) which extends longitudinally to the support (1), in which said common conductor (3) extends along said internal cavity (10). 3. Drilling well (100) according to claim 1 or 2, wherein said electrode (2) comprises a band (20) which surrounds the support element (1), and in which said fins (21) extend from said band (20). 4. Drilling well (100) according to claim 3, in which said fins (21) extend in a direction parallel to the direction of longitudinal development (X) of said elongated support (1). 5. Drilling well (100) according to claim 4, in which said fins (21) extend from said band (20) in the direction of said head end (11) destined to remain on the surface. 6. Drilling well (100) according to claim 4 or 5, in which said fins (21) are connected to said band (20) by means of a deformable connection. 7. Pitch pit (100) according to any one of the preceding claims, in which said elongated support (11) has a tapered end (12) longitudinally opposite to said head end (11). 8. Apparatus for electrical tomography which comprises a plurality of wells (100) made in accordance with any one of the preceding claims and a resistivimeter to which said wells (100) are connected. 9. Method of monitoring the sucking activity of a plant which includes: to. detecting a plurality of resistivity data representative of the characteristics of the soil at different instants by means of a micro tomography apparatus according to claim 8; b. relate the data obtained to the water content in the areas adjacent to the root system of the plant; c. determine a distribution of irrigation water in the subsoil as a function of time; And d. determine the sucking activity of the plant on the basis of this distribution. 10. Method of monitoring the sucking activity of a plant according to claim 9, further comprising driving a plurality of wells (100) into the soil, removing the fins (21) from the elongated support (1) before driving it into the soil.