Customized 1700 degree box type muffle furnace applied in the new energy industry

The customized 1700 degree box type muffle furnace is widely and crucially used in the new energy industry, mainly reflected in lithium battery material processing, solid-state electrolyte synthesis, fuel cell catalyst research, and solar material preparation. Its high temperature stability, precise temperature control, and customization capabilities provide reliable support for the research and production of new energy materials. The following is a specific analysis:

1. Lithium battery material processing
Sintering of positive electrode materials: In the preparation process of lithium battery positive electrode materials (such as lithium nickel cobalt manganese oxide and lithium iron phosphate), a customized 1700 degree box type muffle furnace is used for high-temperature sintering, which can optimize the crystal structure of the material and improve its charge and discharge performance.
Negative electrode material treatment: For new negative electrode materials such as silicon-based negative electrode materials, high-temperature treatment can improve their cycling stability and conductivity. Customized muffle furnaces can provide a stable high-temperature environment to meet the needs of negative electrode material processing.

2. Solid state electrolyte synthesis
Preparation of oxide electrolytes: The synthesis of solid-state battery electrolytes (such as Li ∝ PO ₄) requires a high-temperature environment to achieve densification. The customized 1700 degree box type muffle furnace achieves a fully automatic process of “heating → constant temperature → pressurization → cooling” through a programmable control system, which can prepare electrolyte sheets with higher density and improve efficiency by many times compared to traditional step-by-step processes.
Sulfide electrolyte treatment: Sulfide electrolytes have high ionic conductivity at high temperatures, but need to be treated in an inert atmosphere to prevent oxidation. Customized muffle furnaces can integrate multiple gas control systems, supporting the introduction of inert gases such as hydrogen and argon to meet the processing needs of sulfide electrolytes.

3. Research on Fuel Cell Catalysts
Catalyst preparation: The preparation of fuel cell catalysts (such as platinum based catalysts) requires a high-temperature environment to optimize the active sites of the catalyst. Customized 1700 degree box type muffle furnace can provide a stable high-temperature environment and support the preparation and optimization of catalysts.
Catalyst performance testing: During the catalyst performance testing process, it is necessary to simulate the high-temperature environment under actual reaction conditions. Customized muffle furnaces can integrate in-situ characterization interfaces, reserve interfaces for detection equipment such as spectrometers and mass spectrometers, achieve dynamic monitoring of high-temperature processes, and provide theoretical support for the research and application of catalysts.

4. Preparation of solar materials
Silicon based material processing: In the preparation process of silicon-based materials for solar cells, high-temperature treatment can improve the crystal structure of the material and enhance the photoelectric conversion efficiency. Customized 1700 degree box type muffle furnace can provide a stable high-temperature environment to meet the processing needs of silicon-based materials.
Research on Perovskite Materials: Perovskite solar cells, as a new type of solar cell, require high-temperature environments for material research to optimize material performance. Customized muffle furnaces can support high-temperature synthesis and annealing treatment of perovskite materials, promoting the research and application of perovskite solar cells.

5. The application of customized advantages in the new energy industry
Temperature range and temperature control accuracy: The customized 1700 degree box type muffle furnace can provide a high temperature environment of up to 1700 ℃, and is equipped with an intelligent temperature control system with a temperature control accuracy of ± 1 ℃, meeting the strict requirements of new energy materials for high temperature environments.
Flexibility of atmosphere control: It can integrate multiple gas control systems, support the introduction of corrosive gases such as hydrogen and ammonia, or achieve non oxidizing sintering through vacuum interfaces, meeting the diverse needs of new energy materials for atmosphere control.
Customization of furnace size and structure: The furnace size and structure can be customized according to the processing requirements of new energy materials, such as increasing the furnace volume to support kilogram level sample processing, or optimizing the furnace structure to improve temperature uniformity.
Customization of functional modules: Functional modules can be customized according to the special needs of new energy materials, such as adding mechanical load stacking devices to achieve hot pressing sintering experiments, or reserving in-situ characterization interfaces to support dynamic monitoring of high-temperature processes.