BAXIT Synchronous Thermal Analyzer BXT-DSC-TGA-1250

BAXIT Synchronous Thermal Analyzer BXT-DSC-TGA1250

Product Information

Instrument Introduction

        Synchronous thermal analysis combines thermogravimetric analysis (TG) with differential thermal analysis (DTA) or differential scanning calorimetry (DSC). By using the same sample in the same measurement, TG and DTA or DSC information can be obtained synchronously. Thermogravimetric analysis (TG, TGA) is the process of observing the changes in the mass of a sample with temperature or time during heating, constant temperature, or cooling, with the aim of studying the thermal stability and composition of the material. Widely used in research and development, process optimization, and quality monitoring in various fields such as plastics, rubber, coatings, pharmaceuticals, catalysts, inorganic materials, metal materials, and composite materials. Synchronous thermal analysis combines thermogravimetric analysis (TG) with differential thermal analysis (DTA) or differential scanning calorimetry (DSC). By using the same sample in the same measurement, TG and DTA or DSC information can be obtained synchronously.

Instrument usage

        Measure and study the following characteristics of materials:

      DSC/DTA: Melting, crystallization, phase transition, reaction temperature and reaction heat, combustion heat, specific heat

      TG: Calculation of thermal stability, decomposition, oxidation-reduction, adsorption desorption, free water and crystalline water content, composition ratio, etc.

Main features

1. Built in imported quality weighing balance, with internal calibration and temperature compensation functions, can quickly respond to quality changes, and has better accuracy and repeatability;

2. The instrument has a built-in quality level guidance function, and changes in sample position within the scale range do not affect the quality results;

3. The internal balance room is equipped with a constant temperature water bath device to ensure constant temperature, greatly improving the stability of weighing;

4. The instrument can perform experiments on sample weight gain or loss, such as the adsorption and decomposition processes of the sample;

5. The closed ceramic insulation furnace body structure greatly improves signal sensitivity and resolution, and can obtain a more stable baseline;

6. Modular design of furnace body, more flexible mobility, and easier maintenance;

7. The furnace is designed with a dual gas path blowing structure inside, which can better ensure the airtightness of the experimental process;

8. The interior of the furnace is designed with a capillary water circulation refrigeration structure, which wraps around the furnace and is used for cooling the furnace;

9. The furnace body can reserve experimental exhaust gas treatment interfaces according to customer needs, which can be used for secondary analysis of experimental exhaust gas;

10. The sensor bracket is designed with imported materials and equipped with K-type or E-type sensors that can be switched freely through software. The sensor type can be flexibly selected for different testing scenarios, especially suitable for phase transition and vitrification experiments on polymer materials;

11. The sampling frequency of the sensor signal can be set between 0.05-10Hz, making the experimental method more flexible and the data more controllable;

12. The design concept of dual temperature sensors allows for simultaneous testing of both the internal temperature of the furnace and the sample temperature;

13. The fully temperature control system adopts an optimized dynamic PID algorithm, which greatly avoids the shortcomings of traditional PID algorithms and improves the robustness of dual-mode temperature control;

14. It has two experimental modes, FTC and STC, which can be set for more friendly and flexible temperature control, meeting the needs of different application scenarios and experiments. The temperature control during the experimental process is more accurate, the analysis of sensor signals is more efficient, and the experimental effect is accurately controlled;

15. The 12 level program temperature control setting makes the experimen
tal methods more diversified, and the equipment has a cyclic scanning function, with a maximum of 9999 cyclic scanning times set and data automatically saved;

16. The lower and upper computers of the equipment system have multi-point temperature correction functions, which meet the needs of different experimental scenarios and improve the accuracy of temperature testing;

17. The instrument is equipped with an imported high-frequency core control processor, which has faster processing speed and more efficient control;

18. Independent atmosphere control can be achieved through software intelligent settings, and the instrument automatically switches the gas path system, resulting in higher experimental efficiency;

19. The equipment system can conduct experiments on materials related to heating, cooling, and isothermal processes;

20. Adopting a 7-inch 24 bit full-color LCD touch screen, the instrument's status and data are displayed in real-time;

21. The instrument adopts USB bidirectional communication, software intelligent design, baseline deduction function, automatic issuance of experimental reports, automatic plotting of experimental processes, and intelligent processing of various data, such as glass transition temperature, oxidation induction period, melting point and crystallization of substances.

Technical Parameter

Instrument configuration

Note: The required equipment for your company includes a computer, nitrogen cylinder, oxygen cylinder, and accompanying pressure reducing gauge