Recharge station with extendable prongs for mobile robot

We claim: 1. A charging station for a mobile robotic vacuum comprising: a housing; two extendable prongs that extend outward from the housing for a charging mode and retract back into the housing when not in a charging mode; two electrical connector node contacts positioned on the prongs; and a gearbox containing mechanisms for controlling the extension and retraction of the prongs, wherein: the prongs extend from the housing for the charging mode and retract back into the housing when not in the charging mode by rotating 90 degrees around a pivot, the prongs extend outwards from the housing upon detection of an approaching mobile robotic vacuum, and the prongs retract back into the housing when the mobile robotic vacuum leaves the charging station. 2. The charging station of claim 1 wherein the prongs extend outwards from the housing upon the user's command. 3. The charging station of claim 1 wherein the prongs retract back into the housing upon the user's command. 4. The charging station of claim 1 wherein the prongs retract back into the housing when the charging of the mobile robotic vacuum's battery has completed. 5. The charging station of claim 1 wherein the prongs extend outward for a predetermined amount of time. 6. The charging station of claim 2 wherein the prongs extend outward for a predetermined amount of time. 7. The charging station of claim 1 wherein, activation of the gearbox comprises a motor rotating a worm, the worm meshing with a worm gear, the worm gear meshing with a third gear, the third gear activating a prong gear, and the prong gear activating the extension and retraction of the prongs. 8. The method of claim 1 wherein two electrical connector node contacts positioned on the mobile robotic vacuum connect with the two electrical connector node contacts of the prongs to charge a battery of the mobile robotic vacuum. 9. A method of charging a mobile robotic vacuum comprising: detecting by a charging station an approaching mobile robotic vacuum, transforming the charging station into a charging mode upon detecting the approaching mobile robotic vacuum, in response to the charging mode, extending two extendable prongs outwards from a housing of the charging station, connecting electrical connector node contacts positioned on the prongs with respective electrical connector node contacts of the mobile robotic vacuum, charging the mobile robotic vacuum's battery, detecting by the charging station the departing mobile robotic vacuum, transforming the charging station out of the charging mode upon detecting the departing mobile robotic vacuum, and in response to transforming out of the charging mode, retracting the prongs back into the housing of the charging station. 10. The method of claim 9 wherein the prongs extend from the charging station for the charging mode and retract back into the charging station when not in the charging mode by rotating 90 degrees around a pivot. 11. The method of claim 9 wherein the prongs extend outwards from the housing upon the user's command. 12. The method of claim 9 wherein the prongs retract back into the housing upon the user's command. 13. The method of claim 9 wherein the prongs retract back into the housing when the charging of the mobile robotic vacuum's battery has completed. 14. The method of claim 9 wherein the prongs extend outward for a predetermined amount of time. 15. The method of claim 11 wherein the prongs extend outward for a predetermined amount of time. 16. The method of claim 10 wherein, when a motor runs and the gearbox is activated, the prongs extend from the charging station and retract back into the charging station. 17. The method of claim 16 wherein, activation of the gearbox comprises the motor rotating a worm, the worm meshing with a worm gear, the worm gear meshing with a third gear, the third gear activating a prong gear, and the prong gear activating the extension and retraction of the prongs.