ESP with improved deployment for live intervention

What is claimed is: 1 . A method of deploying a submersible pumping installing production tubing in the well; providing an external stator that includes an expansion compensator; securing the external stator and the expansion compensator to the outside of the production tubing; connecting a pump to a lower end of a rotor, wherein the rotor has a central passage that provides a path for fluid discharged from the pump and a rotor seal for preventing sand from becoming trapped between the rotor and the production tubing; lowering the rotor and pump through the inside of the production tubing to a location at which the rotor is positioned inside the production tubing in proximity to the external stator, with the rotor seal in contact with an inner surface of the production tubing; driving the pump with the rotor to discharge fluids out of the well through the production tubing; and directing solids falling through the production tubing above the rotor through the central passage with the rotor seal. 2 . The method of claim 1 , wherein the step of securing the external stator to the outside of the production tubing occurs before the production tubing is installed in the well. 3 . The method of claim 1 , further comprising the step of connecting a tether to the pump before the step of lowering the rotor and pump through the inside of the production tubing. 4 . The method of claim 1 , further comprising the steps of: connecting a power cable to the external stator; and providing electric current to the external stator through the power cable to activate the rotor to drive the pump to produce fluids through the production tubing. 5 . A downhole pumping system for use in producing fluids to the surface through production tubing, the downhole pumping system comprising: a stator mounted to the outside of the production tubing, wherein the stator includes an expansion compensator; a rotor mounted to the inside of the production tubing in proximity to the stator and configured for rotation inside the production tubing, wherein the rotor comprises a rotor seal on top of the rotor, wherein the rotor seal has a conical inner surface and contacts an inside surface of the production tubing; and a pump driven by the rotor. 6 . The downhole pumping system of claim 5 , wherein the stator comprises one or more permanent magnets and wherein the rotor is a powered rotor that receives electrical power through a brushless connection. 7 . The downhole pumping system of claim 5 , wherein the stator is connected to a source of electrical power and configured to apply rotating magnetic fields to the rotor. 8 . The downhole pumping system of claim 5 , wherein the open rotor includes: a central passage through which fluids are produced; and wherein the rotor seal is configured to prevent solids from becoming trapped between the rotor and the production tubing. 9 . The downhole pumping system of claim 5 , wherein the open rotor includes one or more spiraled channels around the outside of the open rotor that provide an auxiliary pumping action. 10 . The downhole pumping system of claim 5 , wherein the stator is integral with the production tubing. 11 . The downhole pumping system of claim 5 , wherein the rotor includes a plurality of bearings that allow the rotor to rotate inside the production tubing. 12 . The downhole pumping system of claim 5 , wherein the pump is connected below the rotor. 13 . A downhole pumping system for use in producing fluids to the surface through production tubing, the downhole pumping system comprising: a stator mounted to an outside of the production tubing, wherein the stator includes an expansion compensator configured to accommodate the expansion and contraction of lubricants in the motor; a rotor mounted to an inside of the production tubing in proximity to the stator and configured for rotation inside the production tubing, wherein the open rotor comprises a rotor seal positioned on an upper surface of the open rotor in contact with the inside of the production tubing, wherein the rotor seal has a conical inner surface; and a shaft connected to the rotor; and a pump driven by the rotor through the shaft. 14 . The downhole pumping system of claim 13 further comprising a one-way coupling between the rotor and the pump, wherein the one-way coupling is configured to prevent the pump from rotating in an unintended direction.