At present, most offshore wind farms use heat exchangers that not only meet basic heat dissipation needs, but also suffer from certain energy waste. The selection of some heat exchangers is too large, resulting in low fluid flow rate, decreased heat transfer efficiency, and increased pump power consumption during low load operation. Due to the complex and ever-changing marine environment, heat exchangers are susceptible to corrosion, scaling, and other issues, further reducing heat transfer performance and increasing energy consumption. ​

Energy saving scheme design, optimizing heat exchanger selection
We will use advanced heat load calculation software to accurately calculate the required heat transfer based on the heating power of wind turbines under different operating conditions, combined with environmental conditions such as seawater temperature, air humidity, etc., to ensure that the selection of heat exchangers matches actual needs and avoid selecting too large or too small. Select a plate type with high heat transfer coefficient and low flow resistance based on the heat dissipation characteristics of offshore wind power. Improve heat exchange efficiency while reducing pump power consumption. Using hydrophilic aluminum foil, a new material with corrosion resistance, high strength, and good thermal conductivity, to manufacture plates can not only extend the service life of heat exchangers, reduce downtime and energy waste caused by corrosion and maintenance, but also improve heat transfer efficiency to a certain extent.