Large high-speed rotary device gap stacking assembly apparatus and assembly method based on digital twin

What is claimed is: 1. A large high-speed rotary device gap stacking assembly apparatus based on digital twin, comprising an assembly apparatus entity, a data acquisition apparatus and an upper computer, wherein the assembly apparatus entity is configured to establish data communication with the upper computer through the data acquisition apparatus, and the upper computer is configured to establish a virtual assembly model; the assembly apparatus entity comprises an air floatation rotary main shaft, a vertical air floatation guide rail, a center-adjusting and inclination-adjusting workbench, an upper left connecting piece, a lower left connecting piece, an upper left transverse measuring rod, a lower left transverse measuring rod and an inductive sensor; the center-adjusting and inclination-adjusting workbench is stacked on the air floatation rotary main shaft, and the center-adjusting and inclination-adjusting workbench is coaxial with the air floatation rotary main shaft; the vertical air floatation guide rail is arranged on the side surface of the air floatation rotary main shaft, the upper left connecting piece and the lower left connecting piece are sequentially arranged on the vertical air floatation guide rail in a sleeving mode from top to bottom, the upper left transverse measuring rod is nested on the upper left connecting piece, and the lower left transverse measuring rod is nested on the lower left connecting piece; the inductive sensor comprises an axial inductive sensor and a radial inductive sensor, the axial inductive sensor is fixed on the upper left transverse measuring rod and is configured to detect axial surface data of rotary parts, and the radial inductive sensor is fixed on the lower left transverse measuring rod and is configured to detect radial surface data of the rotary parts; and the data acquisition apparatus is configured to drive the inductive sensor to acquire data and transmit the data to the upper computer, the upper computer is configured to integrate the acquired data to the virtual assembly model, and synchronously analyze and compute the acquired data and obtain optimal coaxiality of the multi-stage rotary parts in gap stacking. 2. The large high-speed rotary device gap stacking assembly apparatus based on digital twin according to claim 1 , wherein the upper left connecting piece and the lower left connecting piece are configured to slide on the vertical air floatation guide rail in a vertical direction. 3. The large high-speed rotary device gap stacking assembly apparatus based on digital twin according to claim 1 , wherein the upper left transverse measuring rod is configured to move on the upper left connecting piece in a horizontal direction. 4. The large high-speed rotary device gap stacking assembly apparatus based on digital twin according to claim 1 , wherein the lower left transverse measuring rod is configured to move on the lower left connecting piece bin a horizontal direction. 5. The large high-speed rotary device gap stacking assembly apparatus based on digital twin according to claim 1 , wherein the assembly apparatus further comprises a granite base, the air floatation rotary main shaft is embedded in the center position of the granite base, and the vertical air floatation guide rail is fixedly mounted on the granite base. 6. The large high-speed rotary device gap stacking assembly apparatus based on digital twin according to claim 1 , wherein the assembly apparatus further comprises AR glasses, the AR glasses are connected with the upper computer, data information received and computed by the upper computer is displayed on the AR glasses, and thus the data information can be displayed in real time. 7. A large high-speed rotary device gap stacking assembly method based on digital twin, being achieved by using the large high-speed rotary device gap stacking assembly apparatus based on digital twin according to claim 1 , the method comprising the following steps: S1, wearing the AR glasses, establishing data communication between the assembly apparatus entity and the upper computer through the data acquisition apparatus by using a virtual-real registration technology, and establishing the virtual assembly model through the upper computer; S2, placing a to-be-tested rotary part on the center-adjusting and inclination-adjusting workbench for fixing; S3, rotating the air floatation rotary main shaft to drive the to-be-tested rotary part to rotate at a constant speed; S4, driving the radial inductive sensor to conduct sampling measurement on a radial mounting reference surface of the to-be-tested rotary part at equal intervals through the data acquisition apparatus and obtaining the radial reference surface eccentricity of the rotary part, transmitting the radial reference surface eccentricity to the virtual assembly model, and displaying the data information on the AR glasses at the same time; S5, driving the axial inductive sensor to conduct sampling measurement on an axial mounting reference surface of the to-be-tested rotary part at equal intervals through the data acquisition apparatus and obtaining the axial reference surface eccentricity of the rotary part, transmitting the axial reference surface eccentricity to the virtual assembly model, and displaying data information on the AR glasses at the same time; S6, arranging the center-adjusting and inclination-adjusting workbench through the virtual assembly model according to the magnitude and direction of the radial reference surface eccentricity and the axial reference surface eccentricity of the rotary part and making the rotary part and the center-adjusting and inclination-adjusting workbench concentric; S7, driving the radial inductive sensor to conduct sampling measurement on a radial mounting measurement surface of the rotary part at equal intervals through the data acquisition apparatus and obtaining the concentricity of the rotary part, and transmitting the concentricity to the virtual assembly model; driving the axial inductive sensor to conduct sampling measurement on an axial mounting measurement surface of the rotary part at equal intervals through the data acquisition apparatus and obtaining the perpendicularity of the rotary part, and transmitting the perpendicularity to the virtual assembly model; S8, driving the inductive sensor to measure all the rotary parts required for assembly through the data acquisition apparatus and obtaining the concentricity and the perpendicularity of the multi-stage rotary parts, transmitting the concentricity and the perpendicularity to the virtual assembly model, and displaying data information on the AR glasses at the same time; S9, integrating the collected data information through the virtual assembly model, and analyzing and computing an accumulated eccentric error generated by gap stacking of the multi-stage rotary parts through the upper computer according to the concentricity and the perpendicularity of the multi-stage rotary parts; S10, computing the optimal coaxiality of the multi-stage rotary parts in gap stacking through the upper computer according to the accumulated eccentric error generated by gap stacking of the multi-stage rotary parts, and displaying the optimal coaxiality of the multi-stage rotary parts in gap stacking on the AR glasses; and S11, controlling the assembly process by using the virtual assembly model and the optimal coaxiality of the multi-stage rotary parts in gap stacking displayed on the AR glasses. 8. The large high-speed rotary device gap stacking assembly method based on digital twin according to claim 7 , wherein the accumulated eccentric error generated by gap stacking of the multi-stage rotary parts in step S 9 is specifically as follows: