OEM ODM High Temperature Heat Exchanger Corrosion Resistant

High Temperature Heat Exchange Box

Here are some key features and considerations related to high-temperature heat exchange boxes:

Temperature Resistance: High-temperature heat exchange boxes are specifically designed to withstand and operate at extremely high temperatures. They are constructed using materials with excellent thermal stability and resistance to thermal expansion, such as refractory metals or ceramics. These materials can withstand temperatures ranging from several hundred degrees Celsius to over 1000 degrees Celsius.

Heat Transfer Mechanisms: High-temperature heat exchange boxes facilitate heat transfer through various mechanisms, including conduction, convection, and radiation. The design and configuration of the heat exchange surfaces and flow paths are optimized to maximize heat transfer efficiency while ensuring structural integrity at high temperatures.

Fluid Compatibility: The materials used in high-temperature heat exchange boxes must be compatible with the fluids being processed. They should resist corrosion, oxidation, and chemical reactions that may occur at high temperatures. Different materials and coatings can be employed to enhance the compatibility and durability of the heat exchange surfaces.

Design and Construction: High-temperature heat exchange boxes come in various designs to suit specific applications. They may have a shell-and-tube configuration, plate-and-frame arrangement, or other specialized geometries. The construction of the box involves careful consideration of thermal expansion, mechanical stresses, and sealing to ensure long-term reliability at high temperatures.

Insulation and Heat Loss: Given the high temperatures involved, heat loss from the heat exchange box can be significant. Insulation materials are applied to minimize heat loss and improve energy efficiency. The insulation should provide thermal resistance, be stable at high temperatures, and be resistant to degradation over time.

Safety Considerations: High-temperature heat exchange systems require proper safety measures to protect personnel and equipment. Adequate insulation, thermal barriers, and safety interlocks should be in place to prevent accidental contact with hot surfaces and mitigate the risks associated with high-temperature operation.

Since the temperature of the materials leaving the activation furnace is above 900 degrees, there is no better technology in the world for collecting materials using cloth bags. This system is designed with an air-cooled high-temperature heat exchange box and a water circulation heat exchange box. The high temperature of the materials is reduced to about 350 degrees after air cooling, which avoids the temperature drop caused by sudden water cooling and avoids the moisture absorption and staining of the regenerated carbon. Bi phenomenon, and then cooled through a water circulation high-temperature box to a temperature of about 200 degrees that the bag can withstand and captured. Since the temperature emitted by the air-cooled high-temperature box is relatively high, in order to save energy consumption, the exhaust gas from the bag dust collector passes through the jacket of the air-cooled high-temperature box to maximize the temperature emitted and enter the secondary combustion chamber. The temperature of the secondary combustion chamber reduces the combustion frequency of the burner and saves gas.