Coiled tubing connector to electrical submersible pump

The invention claimed is: 1. An apparatus for connecting an electrical submersible pump assembly (ESP) to a string of coiled tubing containing a power cable having power conductors, the ESP and coiled tubing adapted to be installed within a well, the ESP having a pump, a motor, and a pressure equalizer for reducing a pressure difference between motor lubricant in the motor and well fluid surrounding the motor, the apparatus comprising: a tubular housing configured to connect between a lower end of the coiled tubing and an upper end of the motor; upper and lower barriers in the housing, defining an upper chamber above the upper barrier, a center chamber between the upper and lower barriers, and a lower chamber below the lower barrier; upper electrical terminals in the upper barrier configured to connect to the conductors of the power cable, and lower electrical terminals in the lower barrier configured to connect to motor leads of the motor; electrical conductor members in the center chamber extending between the upper and the lower electrical terminals in the upper and lower barriers; upper chamber dielectric fluid, center chamber dielectric fluid, and lower chamber dielectric fluid filling the upper, center and lower chambers, respectively, the upper chamber dielectric fluid, the center chamber dielectric fluid and the lower chamber dielectric fluid being sealed from each other by the upper and lower barriers; an upper opening in the housing for communicating an interior of the coiled tubing with the upper chamber dielectric fluid, enabling thermal expansion of the upper chamber dielectric fluid into the interior of the coiled tubing; the lower chamber being configured to be in fluid communication with motor lubricant in the motor, enabling thermal expansion of the lower chamber dielectric lubricant through the pressure equalizer of the ESP; and center chamber thermal expansion means for allowing thermal expansion of the center chamber dielectric fluid. 2. The apparatus according to claim 1 , wherein the center chamber thermal expansion means operates independently of the thermal expansions of the lower chamber dielectric fluid and the upper chamber dielectric fluid. 3. The apparatus according to claim 1 , wherein the center chamber thermal expansion means comprises: a container located outside of the center chamber; and a conduit having an open end in the center chamber for receiving center chamber dielectric fluid, the conduit extending through one of the barriers into the container to allow thermal expansion of the center chamber dielectric fluid. 4. The apparatus according to claim 3 wherein: the conduit extends through the upper barrier; and the container joins the conduit and comprises a capillary line within the coiled tubing. 5. The apparatus according to claim 1 , wherein the center chamber thermal expansion device comprises: a flexible container located in one of the upper and lower chambers, the container having an exterior immersed in the dielectric fluid within said one of the upper and lower chambers; and a conduit extending from the center chamber to an interior of the flexible container to admit center chamber dielectric fluid. 6. The apparatus according to claim 1 , wherein the center chamber thermal expansion device comprises: a conduit having an open end in the center chamber for admitting the center chamber dielectric fluid, the conduit extending through the upper barrier; a bellows located in the upper chamber, the bellows having one side immersed in the upper chamber dielectric fluid and another side in contact with the center chamber dielectric fluid in the conduit. 7. The apparatus according to claim 1 , wherein the center chamber dielectric fluid comprises a heavier fluid and a lighter fluid. 8. The apparatus according to claim 1 , wherein: the upper opening in the housing communicates upper chamber dielectric fluid with an annulus between the power cable and the coiled tubing. 9. The apparatus according to claim 1 , wherein: the housing has upper and lower housing portions; and the apparatus further comprises: a parting mechanism that selectively allows the upper housing portion to be separated from the lower housing portion to allow retrieval of the coiled tubing in the event the ESP is stuck within a well; and wherein the lower barrier is located within the lower housing portion, preventing well fluid from contact with the motor leads after the upper housing portion has separated from the lower housing portion. 10. A well fluid pumping apparatus for pumping well fluid from a well, comprising: a string of coiled tubing having a power cable therein, defining an annulus between the power cable and the coiled tubing, the power cable having a plurality of power conductors; a connector housing having an upper end secured to the coiled tubing; an electrical submersible pump assembly (ESP) secured to a lower end of the housing, the ESP having a motor filled with a motor lubricant and a pressure equalizer to reduce a pressure differential between the motor lubricant and well fluid in the well; upper and lower barriers in the housing, defining an upper chamber, a lower chamber, and a center chamber between the upper and lower chambers, the upper and lower barriers sealing the center chamber from the upper and lower chambers; upper chamber dielectric fluid in the upper chamber in fluid communication with the annulus in the coiled tubing; lower chamber dielectric fluid in the lower chamber in fluid communication with motor lubricant in the pressure equalizer; center chamber dielectric fluid in the center chamber that is sealed from contact with the upper and lower chamber dielectric fluids by the upper and lower barriers; upper electrical terminals in the upper barrier joined to the power conductors, and lower electrical connections in the lower barrier joined to motor leads of the motor; electrical conductor rods in the center chamber extending between the upper and the lower electrical terminals in the upper and lower barriers; and a thermal expansion device having an inlet within the center chamber and a container portion for allowing center chamber dielectric fluid to expand into the container in response to thermal expansion. 11. The apparatus according to claim 10 , wherein: the housing has upper and lower housing portions; and the apparatus further comprises: a parting mechanism that selectively allows the upper housing portion and the conductor rods to be separated from the lower housing portion to allow retrieval of the coiled tubing in the event the ESP is stuck within a well; and wherein the lower barrier is located within the lower housing portion, preventing well fluid from contact with the motor leads after the upper housing portion has separated from the lower housing portion. 12. The apparatus according to claim 10 , wherein the center chamber dielectric fluid comprises a layer of lighter dielectric fluid overlying and in contact with a layer of heavier dielectric fluid. 13. The apparatus according to claim 10 , wherein during operation of the motor and while installed in a well, a pressure of the upper dielectric fluid within the upper chamber will be less than a pressure of the lower dielectric fluid within the lower chamber. 14. The apparatus according to claim 10 , wherein: the container portion of thermal expansion device comprises a capillary tube within the coiled tubing; and the thermal expansion device further comprises a conduit extending through the upper barrier and the upper chamber to the capillary tube. 15. The apparatus