Device for determining petrophysical parameters of an underground formation

The invention claimed is: 1. A device for determining petrophysical parameters of at least one core sample from an underground formation comprising a fluid, comprising: at least four electrodes distributed over a length of a support comprising an insulating material and configured as a flexible cylindrical sleeve for receiving at least one core sample; means for emitting a variable-frequency electrical current and a means for measuring electrical resistivity in terms of amplitude and phase of the variable-frequency electrical current, two of the electrodes cooperating with the means for emitting and two of the electrodes cooperating with the means for measuring electrical resistivity; means for measuring an electrical potential difference coupled with two of the electrodes; means for automating at least one of measurements performed by the means for measuring an electrical potential difference, means for collecting the measurements and means for analyzing the measurements; means for making laboratory measurements; two of the electrodes contact open cross sections of the at least one core sample; and a length of the support is oriented along an axis of revolution of the support and a process of using the device. 2. The device as claimed in claim 1 , wherein the variable-frequency electrical current ranges from a lower limit between 1 and 20 MHz (Megahertz), and an upper limit between 28 and 32 MHz. 3. The device as claimed in claim 1 , wherein the electrodes comprise nonpolarizable metal material. 4. The device as claimed in claim 1 , comprising at least one of a hydraulic containment and a temperature regulating cell. 5. The device as claimed in claim 1 , wherein a number of the electrodes ranges between 4 and 8. 6. The device as claimed in claim 2 , wherein a number of the electrodes ranges between 4 and 8. 7. The device as claimed in claim 1 , comprising means for measuring at least one of alkalinity, conductivity, and contents of cations-anions, contents of trace elements, and contents of dissolved gas after sampling. 8. The device as claimed in claim 1 , wherein the cylindrical flexible sleeve is a heat-shrinkable sheath and at least two of the electrodes pass through the heat-shrinkable sheath. 9. The device as claimed in claim 2 , wherein the cylindrical flexible sleeve is a heat-shrinkable sheath and at least two of the electrodes pass through the heat-shrinkable sheath. 10. The device as claimed in claim 3 , wherein the cylindrical flexible sleeve is a heat-shrinkable sheath and at least two of the electrodes pass through the heat-shrinkable sheath. 11. The device as claimed in claim 4 , wherein the cylindrical flexible sleeve is a heat-shrinkable sheath and at least two of the electrodes pass through the heat-shrinkable sheath. 12. The device as claimed in claim 1 , comprising means for injecting a working fluid into the at least one core sample and for regulating a flow rate of the working fluid, and a means for measuring fluid pressure in at least two locations of the at least one core sample. 13. The device as claimed in claim 3 , comprising means for injecting a working fluid into the at least one core sample and for regulating a flow rate of the working fluid, and a means for measuring fluid pressure in at least two locations of the core sample. 14. The device as claimed in claim 8 , comprising means for injecting a working fluid into the at least one core sample and for regulating a flow rate of the working fluid, and a means for measuring fluid pressure in at least two locations of the core sample. 15. The device as claimed in claim 1 , wherein the device provides measurements within at least one well drilled into the formation with a portion of the formation being a zone surrounding the well in which the device is inserted, and the electrodes are rings having a diameter greater than a diameter of the support and are distributed along an axis of revolution of the cylinder. 16. The device as claimed in claim 1 , wherein the means for measuring resistivity, the means for measuring electrical potential difference, and the means for emitting an electric current are placed at a surface of the underground formation and cooperate with the electrodes via connections that are resistant to pressure and temperature conditions present during measurements in wells. 17. A process for exploiting an underground formation containing a fluid with a device for determining petrophysical parameters of at least one core sample from the underground formation comprising at least four electrodes distributed over a length of a support configured as a cylindrical flexible sleeve for receiving the at least one core sample comprising an insulating material; means for emitting a variable-frequency electrical current and a means for measuring electrical resistivity in terms of amplitude and phase of the variable-frequency electrical current, two of the electrodes cooperating with the means for emitting and two of the electrodes cooperating with the means for measuring electrical resistivity; means for measuring an electrical potential difference coupled with two of the electrodes; means for automating at least one of the measurements performed by the means for measuring an electrical potential difference, means for collecting the measurements, and means for analyzing the measurements; means for making laboratory measurements; two of the electrodes contact open cross sections of the at least one core sample; and a length of the support is oriented along an axis of revolution of the support, the process comprising the steps of: i. performing measurements for at least one measurement condition of at least spontaneous potential, of spectral induced polarization on the at least one core sample and determining petrophysical parameters representative of the at least one core sample; ii. performing measurements of spontaneous potential and of spectral induced polarization in at least one well; iii. calibrating the measurements performed in the well from measurements performed on the at least one core sample and determining petrophysical parameters representative of the underground formation; and iv. using the petrophysical parameters representative of the underground formation to define a plan for optimal exploitation of the underground formation and exploiting the underground formation using the optimal exploitation plan. 18. The process as claimed in claim 17 , further comprising during step i): a. measuring a pressure gradient induced in the at least one core sample with means for measuring fluid pressure; b. measuring the electric potential difference induced in the at least one core sample with means for measuring the electrical potential difference; and c. measuring a spectral induced polarization within the at least one core sample with the means for measuring the spectral induced polarization and repeating the measurements a), b) and c) for fluid flow rates and for fluid saturations. 19. The process as claimed in claim 18 , wherein the measurements a), b) and c) are repeated for at least one of containment pressures and temperatures. 20. The process as claimed in claim 17 , wherein the petrophysical parameters representative of at least one of the underground formation and of the at least one sample are at least one of relative permeability and saturation. 21. The process as claimed in claim 17 , wherein step ii) is repeated throughout the exploitation of the underground formation.