Magnetic suspension thermobalance based on quick photothermal heating and measurement method thereof

What is claimed is: 1. A magnetic suspension thermobalance based on photothermal heating, the magnetic suspension thermobalance comprising: a sealed container, a reaction tank, a magnetic suspension device, a laser displacement monitoring component, a photothermal heating component and a photothermal heating component displacement device, wherein a gas inlet is disposed on an upper end of the sealed container, a removable cover plate is disposed on a lower end of the sealed container, a gas outlet is disposed on the cover plate, an air flow stabilization device and an infrared temperature measurement component are disposed inside the sealed container, a displacement monitoring window and a heating beam window both made of a transparent material are disposed in a side wall of the sealed container, the air flow stabilization device is fixed below the gas inlet, the infrared temperature measurement component is fixed below the air flow stabilization device, the photothermal heating component and the laser displacement monitoring component are disposed around the sealed container, the photothermal heating component is connected to the photothermal heating component displacement device and is displaceable through the photothermal heating component displacement device, the magnetic suspension device comprises a magnetic suspension float and a magnetic suspension stator, a support stand configured to support the reaction tank is fixedly disposed on an upper portion of the magnetic suspension float, and when measurement is performed, the magnetic suspension stator is located below the cover plate, the reaction tank is placed on the support stand and is placed in the sealed container together with the magnetic suspension float, and the reaction tank, the magnetic suspension float, and the magnetic suspension stator are on a same center axis, the infrared temperature measurement component faces an opening on an upper portion of the reaction tank, a heating beam emitted by the photothermal heating component passes through the heating beam window and focuses on the reaction tank, a monitoring laser beam emitted by the laser displacement monitoring component passes through the displacement monitoring window and irradiates a measurement position of the magnetic suspension float. 2. The magnetic suspension thermobalance based on photothermal heating as claimed in claim 1 , wherein the magnetic suspension thermobalance further comprises a stator lifting and lowering component configured to lift or lower the magnetic suspension stator, and an upper portion of the stator lifting and lowering component is fixedly connected to a lower portion of the magnetic suspension stator. 3. The magnetic suspension thermobalance based on photothermal heating as claimed in claim 2 , wherein the stator lifting and lowering component comprises an electric machine and a screw pair, one end of the screw pair performing a rotation motion is fixedly connected to an output axis of the electric machine, and another end of the screw pair performing a linear motion is fixedly connected to the lower end of the magnetic suspension stator. 4. The magnetic suspension thermobalance based on photothermal heating as claimed in claim 1 , wherein a balancer is disposed outside the magnetic suspension float, an upper portion of the balancer is fixedly connected to the support stand, the upper portion of the magnetic suspension float is embedded inside the balancer from bottom to top, and at least two balancing wings are symmetrically disposed on a center of the balancer. 5. The magnetic suspension thermobalance based on photothermal heating as claimed in claim 4 , wherein a black silicon carbide ceramic cylindrical crucible is adopted for the reaction tank, and a lightweight insulating brick material is adopted to make the support stand and the balancer. 6. The magnetic suspension thermobalance based on photothermal heating according to claim 1 , wherein a number of the photothermal heating component is plural, the photothermal heating components surround the center axis of the reaction tank and are disposed in an array outside the sealed container, and a size and a number of the heating beam window are determined to ensure that each of the photothermal heating components normally irradiates the reaction tank in a measurement process. 7. The magnetic suspension thermobalance based on photothermal heating according to claim 1 , wherein a number of the laser displacement monitoring component is plural, the laser displacement monitoring components are disposed around the center axis of the reaction tank in an array outside the sealed container, and a size and a number of the displacement monitoring window are determined to ensure that each of the laser displacement monitoring components normally irradiates the measurement position of the magnetic suspension float in a measurement process. 8. The magnetic suspension thermobalance based on photothermal heating according to claim 1 , wherein the sealed container is cylindrical-shaped, and the reaction tank, the magnetic suspension float, and the magnetic suspension stator are all located on a center axis of the sealed container when measurement is performed. 9. The magnetic suspension thermobalance based on photothermal heating according to claim 1 , wherein a precision robotic arm is adopted for the photothermal heating component displacement device. 10. The magnetic suspension thermobalance based on photothermal heating according to claim 1 , wherein one or more of a pressure monitoring component, a microscope, and a Raman laser are further disposed in the sealed container. 11. A measurement method of a magnetic suspension b thermobalance based on photothermal heating, wherein the method adopts the magnetic suspension thermobalance as claimed in claim 1 to measure a mass change of a testing sample under a temperature control condition and the method comprises following steps: 1) weighing the testing sample having a mass of g 0 and adding the same into the reaction tank; 2) removing the cover plate, placing the reaction tank on the support stand of the magnetic suspension float, placing the magnetic suspension float on a center of the cover plate, installing the cover plate onto the sealed container, adjusting a position of the magnetic suspension stator to be located directly below the center of the installed cover plate; 3) activating the magnetic suspension device, moving the magnetic suspension stator upwards after a magnetic field stabilizes, so that the magnetic suspension float floats in the sealed container; 4) continuously introducing gas required to maintain a reaction atmosphere into the sealed container, the gas entering from the gas inlet and exiting from the gas outlet, a velocity of flow of the gas being controlled to be a velocity of flow v required by an experiment; 5) activating the laser displacement monitoring component, the monitoring laser beam emitted by the laser displacement monitoring component passing through the displacement monitoring window and irradiating the measurement position of the magnetic suspension float, measuring a real-time position of the magnetic suspension float in the sealed container, adjusting the position of the magnetic suspension stator up and down, causing the magnetic suspension float to float to a measurement zero point position of the laser displacement monitoring component; 6) activating the photothermal heating component, the heating beam emitted by a heating light source of the photothermal heating component passing through the heating beam window, focusing on the reaction tank, and heating the reaction tank; 7) causing the magnetic suspension float to