Life cycle assessment of wicked heat pipes with water as working fluid
سال انتشار: 1403
نوع سند: مقاله کنفرانسی
زبان: انگلیسی
مشاهده: 222
فایل این مقاله در 6 صفحه با فرمت PDF قابل دریافت می باشد
- صدور گواهی نمایه سازی
- من نویسنده این مقاله هستم
استخراج به نرم افزارهای پژوهشی:
شناسه ملی سند علمی:
ICISE10_163
تاریخ نمایه سازی: 24 اردیبهشت 1404
چکیده مقاله:
In this study, a Life Cycle Assessment (LCA) of wicked heat pipes (at a sample heat transfer capacity of ۱۰۰ watts and water as the working fluid) was conducted to provide valuable insights into environmental and economic aspects of such passive heat transfer tool when used with different wall and wick materials. The assessment focuses on five most common heat pipe materials i.e. copper, nickel, steel, ceramic, and aluminum. The study evaluates the environmental footprint of these thermal management systems, considering factors such as CO۲ emissions, water consumption, transportation effects, and the porosity of the wick for making a WHP. For this purpose, a LCA analysis is conducted for five common materials used in heat pipes, including copper, nickel, steel, ceramic, and aluminum. The results of pollutant emissions indicate that the highest carbon dioxide emissions occur for the heat pipe made of nickel, with ۵۰۷.۶ kg of CO۲ emissions, followed by aluminum at ۱۰۲ kg. Ceramic demonstrates the lowest CO۲ emissions, making it the most ecologically sound choice. Additionally, the cost per unit of nickel is the highest at ۱۶.۱ USD, while ceramic is the most cost-effective at ۳.۱۵ USD. Therefore, ceramic could attract significant attention in the competitive market, especially with the new policies of different countries.
کلیدواژه ها:
نویسندگان
Mohammad Mustafa Ghafurian
Dep. of Civil and Mechanical Engineering Thermal Energy, Technical University of Denmark, Lybgby, Copenhagen, Denmark
Brian Elmegaard
Dep. of Civil and Mechanical Engineering Thermal Energy, Technical University of Denmark, Lybgby, Copenhagen, Denmark
Ahmad Arabkoohsar
Dep. of Civil and Mechanical Engineering Thermal Energy, Technical University of Denmark, Lybgby, Copenhagen, Denmark
Peter Weinberger
Institute of Applied Synthetic Chemistry, TU Wien, Vienna, Austria