Fuel supply system for a road vehicle

The invention claimed is: 1. A fuel supply system ( 5 ) for a road vehicle ( 1 ) and comprising: a fuel tank ( 6 ), which presents a central saddle ( 10 and is shaped like a saddle and delimits an inner volume divided into an upper area ( 11 ), which is located above the central saddle ( 10 ), and two lower areas ( 12 ), which are located under the upper area ( 11 ) and are separated from one another by the central saddle ( 10 ); two low-pressure fuel pumps ( 7 ), which are twin pumps, are operated by corresponding electric motors ( 8 ) and each suck from the bottom of a corresponding lower area ( 12 ); at least one high-pressure fuel pump ( 9 ), which receives fuel from both low-pressure fuel pumps ( 7 ); a first control unit ( 17 ), which is configured to control the electric motors ( 8 ) of the two low-pressure fuel pumps ( 7 ); a first level sensor ( 13 ) arranged in the upper area ( 11 ) and is configured to measure a fuel level only in the upper area ( 11 ); and two second level sensors ( 13 ), each arranged in a respective lower area ( 12 ) and configured to measure a fuel level only in the respective lower area ( 12 ); wherein the two lower areas ( 12 ) communicate with one another only and exclusively through the upper area ( 11 ), since there is not direct connection between the two lower areas ( 12 ) on the outside of the fuel tank ( 6 ), wherein the first control unit ( 17 ) is configured to: determine a total fuel quantity (FF) present inside the fuel tank ( 6 ); activate, at least for a given amount of time, both low-pressure fuel pumps ( 7 ), if the total fuel quantity (FF) exceeds a threshold; and always activate one single low-pressure fuel pump ( 7 ) at a time, if the total fuel quantity (FF) is smaller than the threshold. 2. The fuel supply system ( 5 ) according to claim 1 , wherein each level sensor ( 13 ) comprises a float ( 14 ), which is free to vertically move along an entire extension of its area ( 11 , 12 ), and a transducer ( 15 ), which is mechanically connected to the float ( 14 ) and is configured to provide a signal, which is electrically readable and changes as the vertical position of the float ( 14 ) changes. 3. The fuel supply system ( 5 ) according to claim 1 , wherein the first control unit ( 17 ) is configured to pre-emptively apply, to raw signals (R) provided by the three level sensors ( 13 ), a linearisation, which transforms the raw signals (R) provided by the three level sensors ( 13 ) into corresponding filling percentages (F). 4. The fuel supply system ( 5 ) according to claim 3 , wherein the first control unit ( 17 ) is configured to apply the linearisation by means of a conversion table (TB), which is inputted with the raw signal (R) coming from each level sensor ( 13 ) and outputs a corresponding filling percentage (F). 5. The fuel supply system ( 5 ) according to claim 4 , wherein the conversion table (TB) is variable depending on a lateral acceleration and on a longitudinal acceleration to which the fuel tank ( 6 ) is subjected, so as to change a law of conversion as the lateral acceleration and the longitudinal acceleration change. 6. The fuel supply system ( 5 ) according to claim 5 , wherein the change in the conversion table (TB) takes into account both the absolute value of the lateral acceleration and of the longitudinal acceleration and the direction of the lateral acceleration and of the longitudinal acceleration. 7. The fuel supply system ( 5 ) according to claim 1 , wherein a second control unit ( 16 ) is configured to calculate a fuel quantity (FF) present in the entire fuel tank ( 6 ) by means of a combination of signals provided by the three level sensors ( 13 ). 8. The fuel supply system ( 5 ) according to claim 1 , wherein the first control unit ( 17 ) is configured to: establish a target fuel pressure (P fuelTGT ) downstream of the low-pressure fuel pumps ( 7 ); and determine a rotation speed ( ω motor ) of the electric motors ( 8 ) of the two low-pressure fuel pumps ( 7 ) depending on the target fuel pressure (P fuelTGT ). 9. The fuel supply system ( 5 ) according to claim 8 , wherein the first control unit ( 17 ) is configured to control, through feedback, the rotation speed (ω motor ) of the electric motors ( 8 ) of the two low-pressure fuel pumps ( 7 ) using, as feedback variable, a fuel pressure (P fuel ) measured by a pressure sensor ( 19 ) arranged downstream of the low-pressure fuel pumps ( 7 ). 10. The fuel supply system ( 5 ) according to claim 1 , wherein the first control unit ( 17 ), when the total fuel quantity (FF) exceeds the threshold, is configured to cyclically repeat an activation sequence, which consists of four steps and entails activating one single low-pressure fuel pump ( 7 ) for a first amount of time, then activating, for a second amount of time, both low-pressure fuel pumps ( 7 ), then activating the other low-pressure fuel pump ( 7 ) for the first amount of time, and finally activating again, for the second amount of time, both low-pressure fuel pumps ( 7 ). 11. The fuel supply system ( 5 ) according to claim 10 , wherein the second amount of time is smaller than the first amount of time. 12. The fuel supply system ( 5 ) according to claim 1 , wherein the first control unit ( 17 ), when the total fuel quantity (FF) is smaller than the threshold, is further configured to: determine the lower area ( 12 ) where there is the larger quantity of fuel; and always turn on the sole low-pressure fuel pump ( 7 ) associated with the lower area ( 12 ) where there is the larger quantity of fuel. 13. The fuel supply system ( 5 ) according to claim 1 , wherein the first control unit ( 17 ) is configured to: determine whether there is fuel in both lower areas ( 12 ); and turn on both low-pressure pumps ( 7 ), only if there is fuel in both lower areas ( 12 ). 14. The fuel supply system ( 5 ) according to claim 1 , wherein the first control unit ( 17 ) is configured to request a limitation of performances of an internal combustion engine ( 3 ) receiving fuel from the fuel supply system ( 5 ), if there is fuel only in a lower area ( 12 ) and a fuel pressure (P fuel ) measured by pressure sensor ( 19 ) downstream of the low-pressure fuel pumps ( 7 ) is below a limit value. 15. The fuel supply system ( 5 ) according to claim 1 and comprising a second control unit ( 16 ), which is directly connected to the level sensors ( 13 ) and communicates the signals provided by the level sensors ( 13 ) to the first control unit ( 17 ). 16. The fuel supply system ( 5 ) according to claim 15 , wherein the second control unit ( 16 ) is configured to: calculate a total fuel quantity (FF) present in the entire fuel tank ( 6 ); and communicate the total fuel quantity (FF) to a control panel ( 18 ). 17. A method to control the fuel supply system ( 5 ) according to claim 1 and comprising the steps of: measuring a fuel level only in the upper area ( 11 ) by means of the first level sensor ( 13 ); and measuring a fuel level only in each lower area ( 12 ) by means of the corresponding second level sensor ( 13 ). 18. A fuel supply system ( 5 ) for a road vehicle ( 1 ) and comprising: a fuel tank ( 6 ), which presents a central saddle ( 10 ) and thus is shaped like saddle and delimits an inner volume divided into an upper area ( 11 ), which is located above the central saddle ( 10 ), and two lower areas ( 12 ), which are located under the upper area ( 11 ) and are separated from one another by the central saddle ( 10 ); two low-pressure fuel pumps ( 7 ), which are twin pumps, are operated