First of all, acrylic acid, as a polymer, has good high-temperature stability. The pipes and casing of an acrylic tubular heat exchanger are made of acrylic material, which allows it to withstand operation at high temperatures. After strict process design and process control, the acrylic tube is replaced.
The heater is able to operate safely at temperatures of up to 200 °C or more, achieving efficient heat exchange.
Secondly, the acrylic tubular heat exchanger has good thermal conductivity. Since acrylic itself has a high thermal conductivity, it is able to quickly conduct heat in high-temperature media. This advantage allows acrylic tubular heat exchangers to achieve rapid heat transfer results when handling high-temperature media. Compared with other materials, acrylic tubular heat exchangers have higher thermal efficiency and can better meet the requirements of industrial production for heat exchanger equipment.
In addition, the acrylic tubular heat exchanger has good corrosion resistance. At high temperatures, many media can have a corrosive effect on metal materials. The acrylic material has low corrosiveness, which can effectively prevent the corrosion of high-temperature media on heat exchange equipment. Therefore, acrylic tubular heat transfer is used.
It can extend the service life of equipment, reduce the frequency of maintenance and replacement, and reduce production costs.
The high temperature resistance of acrylic tubular heat exchangers also makes them widely used in some special processes. For example, in the petrochemical industry, acrylic tubular heat exchangers can be used to process high-temperature hydrocarbon media, such as ethylene, propylene, etc., to achieve energy efficiency**. In the power industry, acrylic tubular heat exchangers can be used to handle high-temperature boiler exhaust smoke and improve energy efficiency. In the metallurgical industry, acrylic tubular heat exchangers can be used to treat high-temperature slag, the heat energy in the slag.
In a word, acrylic tubular heat exchangers have been widely promoted and applied in industrial applications because of their high temperature resistance. Its high temperature stability, excellent heat conductivity and corrosion resistance enable it to achieve efficient heat transfer at high temperatures. In the future development, acrylic tubular heat exchangers are expected to further improve their high-temperature resistance to meet the needs of more industrial fields for high-temperature heat exchanger equipment.