Multiple reactor and multiple zone polyolefin polymerization

What is claimed is: 1. A process for producing a multimodal polyolefin, comprising: (a) polymerizing ethylene in a first reactor to produce a first polyolefin; (b) polymerizing ethylene in a first reaction mixture in a riser of a second reactor to produce a second polyolefin; (c) passing the first reaction mixture through an upper conduit from the riser to a separator; (d) recovering, in the separator, the second polyolefin from the first reaction mixture; (e) passing the second polyolefin from the separator into a downcomer of the second reactor, optionally via a liquid barrier; (f) polymerizing ethylene in a second reaction mixture in the downcomer to produce a third polyolefin in a downcomer product mixture; (g) passing the downcomer product mixture through a lower conduit from the downcomer to the riser; (h) one of: (1) after step (a) and before steps (b)-(g), receiving the first polyolefin into the second reactor; or (2) before step (a) and after steps (b)-(g), receiving the second polyolefin and the third polyolefin into the first reactor and (i) maintaining a Dean number (Dn) of the first reaction mixture in an elbow connector to be higher than 3,000,000, where Dn=ρVd/μ*(d/2Rc)½, where ρ is a density of the first reaction mixture, V is a circulation velocity of the first reaction mixture, μ is a dynamic viscosity of the first reaction mixture, d is an inner diameter of the elbow connector, and Rc is an inner curvature of the elbow connector, wherein the elbow connector is connected to a top portion of the riser and to an end of the upper conduit. 2. The process of claim 1 , wherein the elbow connector comprises: a first tap on an outside radius of the elbow connector; a second tap on an inside radius of the elbow connector; a first sensing leg coupling the first tap to a differential pressure meter; and a second sensing leg coupling the second tap to the differential pressure meter. 3. The process of claim 1 , wherein a second elbow connector is connected to i) the riser and the lower conduit or ii) the downcomer and the lower conduit, wherein the process further comprises: maintaining a Dean number (D n ) of the second reaction mixture in the second elbow connector to be higher than 3,000,000, where D n =ρVd/μ*(d/2R c ) 1/2 , where ρ is a density of the second reaction mixture, V is a circulation velocity of the second reaction mixture, μ is a dynamic viscosity of the second reaction mixture, d is an inner diameter of the second elbow connector, and R c is an inner curvature of the second elbow connector. 4. The process of claim 1 , further comprising: discharging a portion of the downcomer product mixture containing the multimodal polyolefin through a product discharge conduit of the downcomer. 5. The process of claim 4 , wherein the product discharge conduit is fluidly connected to the downcomer on or near a bottom tangent of the downcomer. 6. The process of claim 4 , wherein the product discharge conduit is fluidly connected to a continuous take-off valve. 7. The process of claim 4 , wherein the product discharge conduit is fluidly connected to a discontinuous take-off valve. 8. The process of claim 4 , wherein the product discharge conduit is connected to the downcomer such that an angle of the product discharge conduit with respect to horizontal is from −1° to about −60°. 9. The process of claim 4 , wherein the product discharge conduit is connected to the downcomer such that an angle of the product discharge conduit with respect to horizontal is from 1° to about 60°. 10. The process of claim 1 , wherein the multimodal polyolefin is a multimodal polyethylene comprising the first polyolefin, the second polyolefin, and the third polyolefin. 11. The process of claim 10 , wherein the first polyolefin is an ethylene homopolymer, wherein the second polyolefin is a first ethylene copolymer, and wherein the third polyolefin is a second ethylene copolymer. 12. The process of claim 1 , further comprising: injecting an anti-static agent into one or more locations of the second reactor. 13. The process of claim 1 , wherein the downcomer product mixture flows through the lower conduit at a velocity that is greater than a saltation velocity of the downcomer product mixture and up to about 30.48 m/s (100 ft/sec). 14. The process of claim 1 , wherein the downcomer product mixture flows through the lower conduit at a velocity that is greater than 110% of a saltation velocity of the downcomer product mixture. 15. The process of claim 1 , further comprising: controlling a level of the second polyolefin in the separator such that the second polyolefin has a residence time of about 1 second to about 30 minutes in the separator. 16. The process of claim 1 , wherein an average residence time of the first reaction mixture in the riser during a single pass is in a range of about 1 second to about 5 minutes. 17. The process of claim 1 , wherein recovering, in the separator, the second polyolefin from the first reaction mixture comprises: separating, by the separator, solid particles in the first reaction mixture from gas in the first reaction mixture, wherein 99 wt. % or more of the solid particles that are separated have a particle size of greater than about 10 μm. 18. The process of claim 1 , wherein passing the first reaction mixture through the upper conduit from the riser to a separator comprises: passing the first reaction mixture into a tangential entrance of the separator at a tangential entrance velocity of from about 15.24 m/s (50 ft/sec) to about 30.48 m/s (100 ft/sec). 19. The process of claim 1 , wherein the first reactor has an internal surface which is polished to a root mean square of less than about 150 microinches. 20. A process for producing a multimodal polyolefin, comprising: (a) polymerizing ethylene in a first reactor to produce a first polyolefin; (b) polymerizing ethylene in a first reaction mixture in a riser of a second reactor to produce a second polyolefin; (c) passing the first reaction mixture through an upper conduit from the riser to a separator; (d) recovering, in the separator, the second polyolefin from the first reaction mixture; (e) passing the second polyolefin from the separator into a downcomer of the second reactor, optionally via a liquid barrier; (f) polymerizing ethylene in a second reaction mixture in the downcomer to produce a third polyolefin in a downcomer product mixture; (g) passing the downcomer product mixture through a lower conduit from the downcomer to the riser; (h) one of: (1) after step (a) and before steps (b)-(g), receiving the first polyolefin into the second reactor; or (2) before step (a) and after steps (b)-(g), receiving the second polyolefin and the third polyolefin into the first reactor; and (i) maintaining a Dean number (D n ) of the second reaction mixture in an elbow connector to be higher than 3,000,000, where D n =ρVd/μ*(d/2R c ) 1/2 , where ρ is a density of the second reaction mixture, V is a circulation velocity of the second reaction mixture, μ is a dynamic viscosity of the second reaction mixture, d is an inner diameter of the elbow connector, and R c is an inner curvature of the elbow connector, wherein the elbow connector is connected to i) the riser and the lower conduit or ii) the downcomer and the lower conduit. 21. The process of claim 20 , wherein the elbow connector comprises: a first tap on an outside radius of the elbow connector; a second tap on an inside radius of the