Charge pump for electric submersible pump (ESP) assembly

What is claimed is: 1. An electric submersible pump (ESP) assembly, comprising: an electric motor having a first drive shaft; a seal section coupled at a lower end to an upper end of the electric motor having a second drive shaft coupled to the first drive shaft; a charge pump assembly disposed downstream of the seal section, wherein the charge pump assembly comprises a third drive shaft coupled to the second drive shaft, a first fluid mover mechanically coupled to the third drive shaft and having a fluid inlet and a fluid outlet, a fluid reservoir concentrically disposed around the third drive shaft and located downstream of the first fluid mover, wherein an inside surface of the fluid reservoir and an outside surface of the third drive shaft define a first annulus that is fluidically coupled to the fluid outlet of the first fluid mover, and a second fluid mover mechanically coupled to the third drive shaft and having a fluid inlet and a fluid outlet, wherein the second fluid mover is located downstream of the fluid reservoir, and wherein the fluid inlet of the second fluid mover is fluidically coupled to the first annulus wherein the charge pump assembly is configured to flow substantially all of a fluid received by the first fluid mover out an outlet disposed at a downstream end of the charge pump assembly; a gas separator assembly coupled at an upstream end to the outlet of the charge pump assembly, having a fourth drive shaft coupled directly or indirectly to the third drive shaft and having an inlet in fluid communication with an outlet of the charge pump assembly, having a gas flow path and liquid flow path separator having a gas phase discharge port open to an exterior of the gas separator assembly and a liquid phase discharge port; and a production pump assembly coupled at an upstream end to a downstream end of the gas separator assembly and having an inlet in fluid communication with the liquid phase discharge port of the gas flow path and liquid flow path separator. 2. The ESP assembly of claim 1 , wherein the first annulus has a volume of at least 18 cubic inches and less than 1000 cubic inches. 3. The ESP assembly of claim 1 , wherein a distance between the fluid intake and the gas phase discharge port of the gas flow path and liquid flow path separator is at least 6 feet and less than 500 feet. 4. The ESP assembly of claim 1 , wherein the fluid reservoir is at least 6 inches long and less than 17 inches long. 5. The ESP assembly of claim 1 , further comprising a spider bearing located within the fluid reservoir that has a central through-hole that surrounds the drive shaft. 6. The ESP assembly of claim 5 , wherein the fluid reservoir is at least 17 inches long and less than 34 inches long. 7. The ESP assembly of claim 1 , wherein the charge pump assembly further comprises a housing, wherein the inside surface of the fluid reservoir is provided by an inside surface of the housing, wherein the first fluid mover and the second fluid mover are located within the housing. 8. The ESP assembly of claim 7 , wherein the first fluid mover comprises at least one centrifugal pump stage, wherein the at least one centrifugal pump stage comprises an impeller mechanically coupled to the third drive shaft and a diffuser retained by the housing. 9. The ESP assembly of claim 1 , wherein the first fluid mover is an auger mechanically coupled to the third drive shaft. 10. The ESP assembly of claim 1 , further comprising a second fluid reservoir concentrically disposed around the third drive shaft and located downstream of the second fluid mover, wherein an inside surface of the second fluid reservoir and an outside surface of the third drive shaft define a second annulus that is fluidically coupled to the fluid outlet of the second fluid mover. 11. The ESP assembly of claim 1 , wherein a maximum axial length of the fluid reservoir where the third drive shaft is not radially supported is between eleven times the diameter of the third drive shaft and fifteen times the diameter of the third drive shaft. 12. The ESP assembly of claim 1 , wherein the upstream end of the gas separator assembly is threadingly coupled to the downstream end of the charge pump assembly. 13. A method of lifting liquid in a wellbore, comprising: running an electric submersible pump (ESP) assembly into a wellbore, wherein the ESP assembly comprises an electric motor having a first drive shaft; a seal section coupled at a lower end to an upper end of the electric motor having a second drive shaft coupled to the first drive shaft; a charge pump assembly disposed downstream of the seal section, wherein the charge pump assembly comprises a third drive shaft coupled to the second drive shaft, a first fluid mover mechanically coupled to the third drive shaft and having a fluid inlet and a fluid outlet, a fluid reservoir concentrically disposed around the third drive shaft and located downstream of the first fluid mover, wherein an inside surface of the fluid reservoir and an outside surface of the third drive shaft define a first annulus that is fluidically coupled to the fluid outlet of the first fluid mover, and a second fluid mover mechanically coupled to the third drive shaft and having a fluid inlet and a fluid outlet, wherein the second fluid mover is located downstream of the fluid reservoir, and wherein the fluid inlet of the second fluid mover is fluidically coupled to the first annulus wherein the charge pump assembly is configured to flow substantially all of a fluid received by the first fluid mover out an outlet disposed at a downstream end of the charge pump assembly; a gas separator assembly coupled at an upstream end to the outlet of the charge pump assembly, having a fourth drive shaft coupled directly or indirectly to the third drive shaft and having an inlet in fluid communication with an outlet of the charge pump assembly, having a gas flow path and liquid flow path separator having a gas phase discharge port open to an exterior of the gas separator assembly and a liquid phase discharge port; and a production pump assembly coupled at an upstream end to a downstream end of the gas separator assembly and having an inlet in fluid communication with the liquid phase discharge port of the gas flow path and liquid flow path separator; turning the third drive shaft of the charge pump assembly by the electric motor of the ESP assembly; drawing reservoir fluid from the wellbore into the charge pump assembly by the first fluid mover of the charge pump assembly; moving the reservoir fluid downstream by the first fluid mover within the charge pump assembly; filling the fluid reservoir of the charge pump assembly with the reservoir fluid; flowing the reservoir fluid from fluid reservoir of the charge pump assembly to the fluid inlet of the gas separator assembly; discharging a first portion of the reservoir fluid via the gas phase discharge port of the gas flow path and liquid flow path separator to an exterior of the gas separator assembly; discharging a second portion of the reservoir fluid via the liquid phase discharge port of the gas flow path and liquid flow path separator to the inlet of the production pump assembly; pumping the second portion of the reservoir fluid by the production pump assembly; and flowing the second portion of the reservoir fluid out of a discharge of the production pump assembly and via a production tubing to a surface location. 14. The method of claim 13 , further comprising: drawing gas from the wellbore into the gas separator by the first fluid mover; flowing the gas downstream by the first fluid mover to