System for ultra-high temperature in-situ fretting fatigue experiment

What is claimed is: 1 . A system for ultra-high temperature in-situ fretting fatigue experiment, comprising: a heat preservation cover defining a mounting space; a heating device arranged in the mounting space; a first test sample made of a nickel-based polycrystal superalloy and configured to simulate a turbine disk; a second test sample made of a nickel-based single-crystal superalloy and configured to simulate a turbine blade, wherein the first test sample and the second test sample are arranged at an upper end of the heating device along a horizontal direction, a mortise is formed at an end of the first test sample facing towards the second test sample, and a tenon configured to mate with the mortise is formed at an end of the second test sample facing towards the first test sample; and a clamping device arranged in the mounting space, wherein the clamping device is configured to be clamped at two ends of the mated first test sample and second test sample, and configured to apply a periodically reciprocating loading along a length direction of the first test sample and the second test sample. 2 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 1 , wherein an observation hole in communication with the mounting space is defined on the heat preservation cover, the observation hole is located in a middle part of a length direction of the heat preservation cover, and the first test sample and the second test sample are mated with each other and movably arranged in the mounting space in such a manner that the mortise and the tenon are located right below the observation hole. 3 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 1 , wherein, in a direction from the first test sample towards the second test sample, the first test sample sequentially comprises a first clamping portion, a first connecting portion, and a first mating portion; and wherein a width of the first connecting portion is smaller than a width of the first clamping portion and a width of the first mating portion, and the mortise is formed on the first mating portion to open towards the second test sample. 4 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 1 , wherein, in a direction from the second test sample towards the first test sample, the second test sample sequentially comprises a second clamping portion, a second connecting portion, and a second mating portion; and wherein a width of the second connecting portion is smaller than a width of the second clamping portion and a width of the second mating portion, and the second mating portion is formed by the tenon. 5 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 1 , wherein the heating device comprises a temperature control device, a heating wire, and a gasket, wherein the temperature control device is configured to adjust a temperature of the heating wire, the first test sample and the second test sample are disposed on the gasket, and the gasket is configured to transfer heat generated by the heating wire towards the first test sample and the second test sample. 6 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 5 , wherein the heating wire is arranged at a lower end of the gasket. 7 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 5 , wherein in a length direction of the heat preservation cover, a length of the gasket is greater than or equal to a total length of the mated first test sample and second test sample. 8 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 5 , wherein the gasket comprises two supporting portions spaced apart from each other along the length direction of the first test sample and the second test sample, and an interconnecting portion connected to the two supporting portions; and wherein one of the two supporting portions is located at an end of the first test sample facing away from the second test sample, the other one of the two supporting portions is located at an end of the second test sample facing away from the first test sample, and the first test sample and the second test sample are disposed on the interconnecting portion. 9 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 8 , wherein the interconnecting portion is formed as a hollow ring located at a position where the first test sample and the second test sample are mated with each other. 10 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 5 , wherein the gasket is made of a special high-temperature resistant material. 11 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 1 , wherein in a length direction of the heat preservation cover, a length of the first test sample is equal to a length of the second test sample. 12 . The system for ultra-high temperature in-situ fretting fatigue experiment according to claim 1 , further comprising a scanning electron microscope (SEM) observation cavity and a vacuum device, wherein the vacuum device is configured to form a vacuum state in the SEM observation cavity.