Electric submersible pump (ESP) with gas handling shroud inlet

What is claimed is: 1. An electric submersible pump (ESP) assembly, comprising: an electric motor; a centrifugal pump mechanically coupled to the electric motor; and a gas handling inverted shroud assembly comprising a shroud inlet and a lower shroud body comprising a first tubing having a first diameter, a taper section coupled to the first tubing above the first tubing that has a diameter that transitions between the first diameter and a second diameter, wherein the second diameter is different from the first diameter, and a second tubing having the second diameter coupled to the taper section above the taper section and coupled to the shroud inlet. 2. The ESP assembly of claim 1 , wherein the taper section is an outward taper section and the second diameter is greater than the first diameter. 3. The ESP assembly of claim 1 , wherein the taper section is an inward taper section and the second diameter is less than the first diameter. 4. The ESP assembly of claim 1 , wherein the shroud inlet comprises directing vanes that are integrated with the shroud inlet. 5. The ESP assembly of claim 1 , wherein the gas handling inverted shroud assembly comprises a shroud clamp having ports. 6. The ESP assembly of claim 1 , wherein the gas handling inverted shroud assembly comprises an upper shroud body tubing located above the shroud inlet of the inverted shroud assembly. 7. An electric submersible pump (ESP) assembly, comprising: an electric motor; a centrifugal pump mechanically coupled to the electric motor; and a gas handling inverted shroud assembly, wherein the inverted shroud assembly comprises a shroud inlet having an inward taper below openings defined by the shroud inlet. 8. A method of artificially lifting fluid in a wellbore by an electric submersible pump (ESP) assembly, comprising: separating a flowing reservoir fluid into a high gas void fraction fluid and a low gas void fraction fluid by inducing a rotational movement in the reservoir fluid by directing vanes of a shroud inlet of an inverted shroud assembly of an ESP assembly, wherein the directing vanes are integrated with the shroud inlet; providing mechanical torque by an electric motor to a centrifugal pump of the ESP assembly; and lifting the low gas void fraction fluid to a wellhead by the centrifugal pump. 9. The method of claim 8 , wherein separating the flowing reservoir fluid into a high gas void fraction fluid and a low gas void fraction fluid comprises increasing a fluid velocity of the reservoir fluid by flowing the fluid past an outward taper of the inverted shroud assembly. 10. The method of claim 8 , wherein separating the flowing reservoir fluid into a high gas void fraction fluid and a low gas void fraction fluid comprises decreasing a fluid velocity of the reservoir fluid by flowing the fluid past an inward taper of the inverted shroud assembly. 11. The method of claim 8 , further comprising cooling the electric motor by flowing reservoir fluid over the outside surface of the electric motor, where the electric motor is located below a seat plate of the inverted shroud assembly. 12. A method of artificially lifting fluid in a wellbore by an electric submersible pump (ESP) assembly, comprising: separating a flowing reservoir fluid into a high gas void fraction fluid and a low gas void fraction fluid by an inverted shroud assembly of an ESP assembly, wherein separating the flowing reservoir fluid into a high gas void fraction fluid and a low gas void fraction fluid comprises exhausting gas bubbles or high gas void fraction fluid out of a port in a shroud clamp of the inverted shroud assembly into a wellbore above the ESP assembly; providing mechanical torque by an electric motor to a centrifugal pump of the ESP assembly; and lifting the low gas void fraction fluid to a wellhead by the centrifugal pump. 13. The method of claim 12 , wherein the inverted shroud assembly comprises an upper shroud body comprising a tubing and coupled at an upper end to the shroud clamp, wherein exhausting gas bubbles or high gas void fraction fluid out of the ports in the shroud clamp avoids recirculating the gas bubbles or high gas void fraction fluid into the shroud inlet. 14. A method of artificially lifting fluid in a wellbore by an electric submersible pump (ESP) assembly, comprising: assembling an ESP assembly proximate to a wellbore, where the ESP assembly comprises an electric motor, a centrifugal pump, and an inverted shroud assembly; coupling the ESP assembly to a production tubing string by securing the inverted shroud assembly to the production tubing string using a shroud clamp, wherein the shroud clamp defines ports in an upper part of the shroud clamp; running the ESP assembly into the wellbore; providing electric power to the electric motor; separating a flowing reservoir fluid into a high gas void fraction fluid and a low gas void fraction fluid by the inverted shroud assembly, wherein gas of the high gas void fraction is provided an escape path by the ports in the upper part of the shroud clamp; and lifting the low gas void fraction fluid by the centrifugal pump to a wellhead located over the wellbore. 15. The method of claim 14 , wherein assembling the ESP assembly comprises assembling the inverted shroud assembly, where the inverted shroud assembly comprises an outward taper section below a shroud inlet of the shroud assembly. 16. The method of claim 14 , wherein assembling the ESP assembly comprises assembling the inverted shroud assembly, where the inverted shroud assembly comprises an inward taper section below a shroud inlet of the shroud assembly. 17. The method of claim 14 , wherein assembling the ESP assembly comprises assembling the inverted shroud assembly, where the inverted shroud assembly comprises a shroud inlet having directing vanes that are integrated with the shroud inlet. 18. The method of claim 14 , wherein the inverted shroud assembly comprises a shroud inlet that has an outward taper below openings defined by the shroud inlet, wherein the openings are axially aligned with a centerline of the shroud inlet and are parallel to each other. 19. The method of claim 14 , wherein the inverted shroud assembly comprises a shroud inlet that has an inward taper below openings defined by the shroud inlet, wherein the openings are axially aligned with a centerline of the shroud inlet and are parallel to each other. 20. The method of claim 14 , wherein the inverted shroud assembly comprises an upper shroud body comprising a tubing and coupled at an upper end to the shroud clamp.