Synchronous and dynamic loading method in electro-magneto-thermo-mechanical multi-field coupling conditions

What is claimed is: 1. A synchronous and dynamic loading method in electro-magneto-thermo-mechanical multi-field coupling conditions, comprising: making preparations to install a test carrier, a rotating body, a pulse power supply and a pressure device, fixing a test object on the test carrier, and respectively connecting the pulse power supply with the test carrier and the rotating body through connecting conductors, wherein the rotating body is positioned above the test object, the pressure device is arranged above the rotating body, and pressure is applied to the rotating body; turning on the pulse power supply to apply maximum pulse current to the test object to realize loading under extreme electric field and magnetic field conditions; simultaneously driving the rotating body to rotate at a high speed, so that the rotating body rubs against the test object to generate friction heat, and realizing loading in an extreme-temperature field combined with Joule heat and arc heat; and synchronously applying pressure to the rotating body by the pressure device, and realizing loading of an extreme force combined with gravity and an electromagnetic force of the rotating body and the friction force between the rotating body and the test object; and measuring the pulse current, a pulse voltage, and the temperature, stress and electromagnetic signals of the test object in real time, and regulating and controlling an output current of the pulse power supply, the rotating speed of the rotating body, the output pressure of the pressure device to realize synchronous and dynamic loading in electro-magneto-thermo-mechanical multi-field coupling conditions; wherein during the turning, the Joule heat and arc heat of the pulse current are regulated and controlled through the output current of the pulse power supply, the output pressure of the pressure device and the rotating speed of the rotating body, and a maximum temperature rise rate is realized through a combined action of friction heat. 2. The synchronous and dynamic loading method in electro-magneto-thermo-mechanical multi-field coupling conditions according to claim 1 , wherein during the turning, maximum current density is realized by regulating and controlling the pulse current and rotating speed of the rotating body. 3. The synchronous and dynamic loading method in electro-magneto-thermo-mechanical multi-field coupling conditions according to claim 2 , wherein the current density depends on the pulse current, a contact area and material properties, and the current density is calculated by the relationship among the current, the contact area and the current density. 4. The synchronous and dynamic loading method in electro-magneto-thermo-mechanical multi-field coupling conditions according to claim 3 , wherein a calculation formula of the current density is as follows: J = I S ; wherein, I is pulse current, S is the area of a single contact point, J is current density; wherein, S = F n ⁢ ζ ⁢ H , n is a number of conductive spots, ζ is correction factor, H is contact hardness, and F is contact pressure.