Rocket-engine turbopump

What is claimed is: 1. A rocket-engine turbopump comprising: a main shaft rotatably supported; a pump section including an impeller attached to one end of the main shaft; and a turbine section including: a disk attached to the other end of the main shaft, rotor blades provided on an outer periphery of the disk, and nozzles provided inclined to an entrance plane of a blade cascade constituted of the rotor blades, the nozzles having axisymmetric and circular cross sections and arranged in two rows along a circumferential direction of the main shaft in a plane orthogonal to the main shaft, wherein outlets of the nozzles in one of the two rows and outlets of the nozzles in the other of the two rows are alternately positioned around the main shaft so that a phase shift between ejection areas of the nozzles in the one of the two rows and ejection areas of the nozzles in the other of the two rows in the entrance plane is within a range of an angle from ¼ to ¾ of a circumferential angle defined by each ejection area with respect to a center of the main shaft. 2. The rocket-engine turbopump according to claim 1 , wherein the nozzles are arranged so that projected areas of the outlets of the nozzles to the entrance plane along central axes of the nozzles are positioned within the entrance plane. 3. The rocket-engine turbopump according to claim 1 , wherein the outlets of the nozzles in one of the two rows and the outlets of the nozzles in the other of the two rows have mutually different cross-sectional areas. 4. The rocket-engine turbopump according to claim 2 , wherein the outlets of the nozzles in one of the two rows and the outlets of the nozzles in the other of the two rows have mutually different cross-sectional areas. 5. The rocket-engine turbopump according to claim 1 , wherein a nozzle in one row of the two rows is referred to as a first nozzle, a nozzle in the other row of the two rows is referred to as a second nozzle, an ellipse of the outlet of the first nozzle projected on the entrance plane along a central axis of the first nozzle is referred to as the first ellipse, and an ellipse of the outlet of the second nozzle projected on the entrance plane along a central axis of the second nozzle is referred to as the second ellipse, and a major axis of the first ellipse and a major axis of the second ellipse are inclined in mutually opposite directions or in the same direction in the entrance plane. 6. The rocket-engine turbopump according to claim 2 , wherein a nozzle in one row of the two rows is referred to as a first nozzle, a nozzle in the other row of the two rows is referred to as a second nozzle, an ellipse of the outlet of the first nozzle projected on the entrance plane along the central axis of the first nozzle is referred to as the first ellipse, and an ellipse of the outlet of the second nozzle projected on the entrance plane along the central axis of the second nozzle is referred to as the second ellipse, and a major axis of the first ellipse and a major axis of the second ellipse are inclined in mutually opposite directions or in the same direction in the entrance plane. 7. The rocket-engine turbopump according to claim 3 , wherein a nozzle in one row of the two rows is referred to as a first nozzle, a nozzle in the other row of the two rows is referred to as a second nozzle, an ellipse of the outlet of the first nozzle projected on the entrance plane along a central axis of the first nozzle is referred to as the first ellipse, and an ellipse of the outlet of the second nozzle projected on the entrance plane along a central axis of the second nozzle is referred to as the second ellipse, and a major axis of the first ellipse and a major axis of the second ellipse are inclined in mutually opposite directions or in the same direction in the entrance plane. 8. The rocket-engine turbopump according to claim 4 , wherein a nozzle in one row of the two rows is referred to as a first nozzle, a nozzle in the other row of the two rows is referred to as a second nozzle, an ellipse of the outlet of the first nozzle projected on the entrance plane along the central axis of the first nozzle is referred to as the first ellipse, and an ellipse of the outlet of the second nozzle projected on the entrance plane along the central axis of the second nozzle is referred to as the second ellipse, and a major axis of the first ellipse and a major axis of the second ellipse are inclined in mutually opposite directions or in the same direction in the entrance plane. 9. The rocket-engine turbopump according to claim 1 , wherein each of the nozzles is a De Laval nozzle. 10. The rocket-engine turbopump according to claim 2 , wherein each of the nozzles is a De Laval nozzle. 11. The rocket-engine turbopump according to claim 3 , wherein each of the nozzles is a De Laval nozzle. 12. The rocket-engine turbopump according to claim 4 , wherein each of the nozzles is a De Laval nozzle. 13. The rocket-engine turbopump according to claim 5 , wherein each of the nozzles is a De Laval nozzle. 14. The rocket-engine turbopump according to claim 6 , wherein each of the nozzles is a De Laval nozzle. 15. The rocket-engine turbopump according to claim 7 , wherein each of the nozzles is a De Laval nozzle. 16. The rocket-engine turbopump according to claim 8 , wherein each of the nozzles is a De Laval nozzle.