This website requires certain cookies to work and uses other cookies to help you have the best experience. By visiting this website, certain cookies have already been set, which you may delete and block. By closing this message or continuing to use our site, you agree to the use of cookies. Visit our updated privacy and cookie policy to learn more.
This Website Uses Cookies By closing this message or continuing to use our site, you agree to our cookie policy. Learn MoreThis website requires certain cookies to work and uses other cookies to help you have the best experience. By visiting this website, certain cookies have already been set, which you may delete and block. By closing this message or continuing to use our site, you agree to the use of cookies. Visit our updated privacy and cookie policy to learn more.
Getting the most out of your combustion system means focusing on higher productivity, lower costs, reduced environmental impact and increased product quality.
Using a thermal-capture burner is the single-most-important factor in getting the most energy out of each dollar you spend on fuel. Understanding how this works can help you pick the right burner for your application.
Energy costs represent a large fraction of the operating cost of an industrial furnace, most of which use natural gas as their source of heat. Companies that operate thermal-processing systems can maintain a competitive edge with efficient fuel use while minimizing the emission of CO2 and NOx.
In today’s business climate, companies that operate thermal-processing systems in the recycling area must focus on higher productivity, increased product quality and reduced environmental impact. The recycling of aluminum scrap involves combustion as the main heat source, so meeting these challenges at the lowest cost depends largely on the quality and integrity of the combustion system and its interaction with the scrap.
There are at least two ways to describe a furnace’s thermal performance. The percent-available heat[1] indicates thermal efficiency, while the adiabatic flame temperature[2] indicates heat-transfer intensity. Both factors can be used to indicate a furnace’s productivity.