Lateral stability system

The invention claimed is: 1. A telescopic handler comprising a frame, a telescopic boom, an equipment, and a lateral stability system, the frame supporting the telescopic boom, the telescopic handler being configured and adapted to lift and lower the telescopic boom in a vertical plane, the telescopic boom being telescopically extendable and retractable, the telescopic boom having a distal end, the equipment being fitted at the distal end, the equipment being configured and adapted to support a load and to laterally translate the load in a first direction perpendicular to said vertical plane and in a second direction opposite to the first direction, the lateral stability system comprising: (a) a first sensing means configured for determining a position of said load relative to a center plane of said equipment and for producing an imbalance signal as a function of the position of the load; (b) a processing unit configured to enable or inhibit movements of said telescopic boom; and (c) a fourth sensing means connected to said processing unit and configured for determining the amount of telescopic extension of said telescopic boom, wherein a fourth safety parameter is a function of the value of a signal produced by said fourth sensing means and said movements of said telescopic boom are further enabled or inhibited according to said fourth safety parameter; wherein said first sensing means is connected to said processing unit, and wherein said movements of said telescopic boom are enabled or inhibited according to a first safety parameter, said first safety parameter being a function of the value of said imbalance signal produced by said first sensing means. 2. The telescopic handler according to claim 1 , wherein said equipment includes a loading fork, whose tines are moved by respective actuators, wherein said first sensing means includes at least one position sensor for each actuator. 3. The telescopic handler according to claim 1 , comprising a second sensing means configured for sensing the weight of the load supported by said equipment, the second sensing means being connected to said processing unit, wherein a second safety parameter is a function of the value of a signal produced by said second sensing means and said movements of said telescopic boom are further enabled or inhibited according to said second safety parameter. 4. The telescopic handler according to claim 3 , wherein said processing unit is further configured to process the first and second safety parameters and to calculate a torque value, and said movements of said telescopic boom are further enabled or inhibited according to the torque value. 5. The telescopic handler according to claim 4 , wherein the processing unit is further configured to process the second safety parameter and to calculate a danger value, and said movements of said telescopic boom are further enabled or inhibited according to the torque and danger values. 6. The telescopic handler according to claim 1 , comprising a third sensing means configured for determining the angular position of said telescopic boom relative to the frame, the third sensing means being connected to said processing unit, wherein a third safety parameter is a function of the value of a signal produced by said third sensing means and said movements of said telescopic boom are further enabled or inhibited according to said third safety parameter. 7. The telescopic handler according to claim 1 , further comprising at least one slope sensing device connected to said processing unit and configured for producing a slope signal. 8. The telescopic handler according to claim 7 , further comprising levelling means configured for changing or maintaining the positioning of the frame relative to the horizon, wherein said processing unit is further configured for controlling said levelling means in accordance with the value of said slope signal. 9. The telescopic handler according to claim 1 , wherein the lateral translation of the load is in a direction orthogonal to the direction of extension of the telescopic boom. 10. The telescopic handler according to claim 1 , wherein the telescopic boom is fixed such that it cannot rotate around a vertical axis. 11. The telescopic handler according to claim 1 , wherein the vertical plane and the center plane are coincident. 12. A method for ensuring the lateral stability of a telescopic handler, the method comprising: providing a telescopic handler according to claim 1 ; sensing the position of the load relative to the center plane of said equipment; producing an imbalance signal as a function of the position of the load; determining the first safety parameter as a function of the value of the imbalance signal; and enabling or inhibiting movements of said telescopic boom based at least on said first safety parameter. 13. The method according to claim 12 , further comprising: sensing the weight of the load supported by said equipment; determining the second safety parameter as a function of the weight of the load, enabling or inhibiting movements of said telescopic boom based at least on the first and second safety parameters. 14. The method according to claim 12 , wherein the lateral translation of the load is in a direction orthogonal to the direction of extension of the telescopic boom. 15. A non-transitory computer-readable medium storing instructions that, when executed by a computer, perform the steps of the method according to claim 12 .