Synchronous thermal analyzer is a kind of experimental equipment widely used in material science, chemistry, physics and other fields. It combines two techniques, thermogravimetric analysis (TGA) and differential thermal analysis (DSC), to simultaneously measure the mass and heat changes of the sample, providing a wealth of information about the thermal properties and chemical reactions of the sample.
The main components of a synchronous thermal analyzer include heater, temperature controller, thermocouple, sample station and data acquisition system. The heater is used to raise the temperature of the sample, the temperature controller precisely controls the temperature of the heater, the thermocouple measures the temperature change of the sample, the sample table places the sample, and the data acquisition system records the data of the mass change and the heat change.
The advantage of synchronous thermal analyzer is its high accuracy and versatility. By measuring mass changes and heat changes, the thermal properties and chemical reactions of the sample can be more accurately determined. In addition, synchronous thermal analyzers can also be used to study the thermal stability and thermal decomposition process of materials, as well as the thermal effects and kinetic parameters of chemical reactions.
When using a synchronous thermal analyzer, special attention needs to be paid to sample preparation and handling. Because different samples may have different thermal properties and chemical reactions, the samples need to be properly treated to ensure the accuracy and reliability of the experimental results.
Overall, a synchronous thermal analyzer is a powerful experimental device capable of providing detailed information about the thermal properties and chemical reactions of materials. It has been widely used in various fields of research and is of great significance to promote scientific research and industrial development.