Fracturing blender system and method using liquid petroleum gas

What is claimed is: 1. An electric blender system, operatively associated with a dedicated electric power source, capable of providing a blended fracturing fluid to a fracturing pump capable of delivering fracturing fluid to a wellbore, comprising: a blender tub; a fluid additive system; a fluid addition source hopper; an inlet electric motor configured to drive an inlet pump, in communication with a fluid additive source and capable of pumping the fluid additive source into and out of the blender tub; and a control system capable of linking the electric blender system and the fracturing pump under a single point of control for syncing, or slaving, the electric blender system to a fracturing pump; wherein the fluid additive system is configured to deliver approximately 120 bbl/min of a blended fracturing fluid to a wellbore, and further comprises an additive hopper, an auger, and a discharge pump, wherein the auger and discharge pump are driven by an electric discharge motor; wherein the discharge pump delivers the fluid additive source out of the blender tub; wherein the inlet pump delivers the fluid additive source into and out of the blender tub; and wherein the electric blender system can be removed from service and replaced without disrupting the delivery to the wellbore operation. 2. The electric blender system of claim 1 , wherein the fracturing fluid comprises a liquefied petroleum gas. 3. The electric blender system of claim 2 , wherein the liquified petroleum gas comprises one or more gases selected from propane, butane, propylene, and butylene gas. 4. The electric blender system of claim 1 , configured to process approximately 120 bbl/min of blended fracturing fluid for delivery to a wellbore. 5. The electric blender system of claim 1 , capable of mixing approximately 15 t/min of sand with the blended fracturing fluid. 6. The electric blender system of claim 1 , wherein the electric power source supplies electric power to the inlet electric motor, and the electric discharge motor. 7. The electric blender system of claim 1 , further comprising a first inlet manifold, in fluid communication with the inlet pump, for delivering unblended fracturing fluid to the blender tub. 8. The electric blender system of claim 7 , further comprising an inlet crossing line, coupled to the inlet manifold, and an additional inlet manifold, for delivering unblended fracturing fluid therebetween. 9. The electric blender system of claim 7 , wherein the inlet electric motor is adapted to drive the pumping of the fracturing fluid from the inlet manifold and the second inlet manifold, to the electrically driven blender unit and the additional electrically driven blender unit. 10. The electric blender system of claim 1 , further comprising a first outlet manifold coupled to a first electrically driven blender unit, for delivering blended fracturing fluid away therefrom to the wellbore operation. 11. The electric blender system of claim 10 , wherein the first inlet manifold, and first outlet manifold, are configured to be in fluid communication with one or more additional electric blender systems via additional inlet manifolds and additional outlet manifolds. 12. The electric blender system of claim 11 , further comprising a second inlet manifold, coupled to a second electrically driven blender unit, for delivering the blended fracturing fluid thereto. 13. The electric blender system of claim 10 , wherein the first electrically driven blender unit, has a first electric motor that receives electric power from the dedicated electrical power source. 14. The electric blender system of claim 10 , further comprising an outlet crossing line, coupled to the first outlet manifold, in fluid communication with an additional outlet crossing line ( 51 ), coupled to an additional outlet manifold, wherein the outlet crossing line, and the additional outlet crossing line, are in fluid communication thereby allowing for the delivery of unblended fracturing fluid between the electrically driven blender unit and an additional electrically driven blender unit. 15. The electric blender system of claim 10 , further comprising a first electric blending motor, coupled to the electrically driven blender unit, and an additional electrically driven blender unit, for pumping unblended fracturing fluid. 16. The electric blender system of claim 15 , wherein the first electrically driven blender unit uses the inlet electric motor to pump unblended fracturing fluid to the blender tub. 17. The electric blender system of claim 1 , further comprising an additive electric motor operatively coupled to the auger. 18. A method for providing an electric blender unit portion of an electric blender system, operatively associated with a dedicated electric power source to process and blend a fracturing fluid capable of delivery to a wellbore, comprising: providing a blender tub; providing a fluid additive system; providing a fluid addition source hopper; providing an inlet electric motor configured to drive an inlet pump in communication with a fluid source, to pump the fluid source into the blender tub; wherein the fluid additive system is configured to deliver approximately 120 bbl/min of a blended fracturing fluid to a wellbore, and further comprises an additive hopper, an auger, and a discharge pump; wherein the auger and discharge pump are driven by an electric discharge motor, and wherein the discharge pump delivers the fluid additive source out of the blender tub; and providing a control system that controls the electric blender system and the fracturing pump under a single point of control that syncs, or slaves, the electric blender system to a fracturing pump [.] operating the auger to add the fluid additive source to the hopper to pump to the blender tub and deliver blended fracturing fluid to a wellbore. 19. The method of claim 18 , wherein the fracturing fluid comprises a liquefied petroleum gas. 20. The method of claim 19 , wherein the liquified petroleum gas comprises one or more gases selected from propane, butane, propylene, and butylene gas. 21. The method claim 18 , wherein approximately 120 bbl/min of a fracturing fluid is blended for delivery to a wellbore operation. 22. The method of claim 18 , wherein approximately 15 t/min of sand are mixed with the blended fracturing fluid. 23. The method of claim 18 , wherein the electric power source supplies electric power to the inlet electric motor, and the electric discharge motor. 24. The method of claim 18 , further comprising using a first inlet manifold, in fluid communication with the inlet pump, for delivering unblended fracturing fluid to the blender tub. 25. The method of claim 24 , further comprising a second inlet manifold, coupled to a second electrically driven blender unit, used for delivering unblended fracturing fluid the wellbore. 26. The method of claim 25 , wherein the first electric blending motor is adapted to drive the pumping of the fracturing fluid from the inlet manifold and the second inlet manifold, to the electrically driven blender unit and the additional electrically driven blender unit. 27. The method of claim 24 , further comprising an inlet crossing line, coupled to the first inlet manifold, and an additional inlet manifold, used for delivering unblended fracturing fluid between the inlet manifold and the additional inlet manifold.