Energy Consumption and Carbon Footprint of Secondary Aluminum Cast House

Wei, Wenjing

January 2012

Primary aluminum production brings about severe environmental burden due to its energy intensive process.  Secondary aluminum production contributes to cutting off high energy demand around 90-95% and greenhouse gas emission by remelting scraps. However, previous research indicates melting furnace’s energy efficiency in secondary plant is still very low, which is around 26-29% and more than 70% heat is lost in different way. The objective of this project is to investigate energy consumption and greenhouse gas (GHG) emission in secondary aluminum cast house through process analysis. The result offers a comprehensive overview to aid decision-maker to compare energy consumption and environmental impacts caused by different product or process. This project has been done in collaboration with SAPA Heat Transfer. This project consists of two tasks. First task is aimed to give an overview of annual energy distribution and carbon footprint of per ton aluminum slab in SAPA cast house. In order to analyze energy distribution, mass and energy conservation has been applied for calculation. Meanwhile, International standard method, life cycle assessment, has been used to evaluate greenhouse gas contribution of the whole production process. The second task intends to investigate two effects (melting furnace type, raw material type) on products’ energy consumption and carbon footprint.  Melting furnace’s effect is compared by selecting electric induction furnace and oxy-fuel furnace. On the other hand, raw material’s effect is studied by comparison of four different cast house products which have different raw material recipe. Calculation and analysis results indicates that per ton Sapa cast house aluminum slab consumes energy 3826MJ and contributes to 306kgCO2eq. green house gas. Meanwhile, comparison results show that oxy-fuel melting furnace has higher energy efficiency than electric induction furnace, however, it contributes much more GHG due to consumption of propane fuel. In addition, primary ingot has been concluded as distinct carbon footprint contribution than others contributors (i.e. fuel) for Sapa cast house’s slab.

secondary aluminum cast house

energy consumption

carbon footprint

melting furnace

efficiency

Metallurgy and Metallic Materials

Metallurgi och metalliska material

Energy efficiency of smelting of scrap aluminium in HPDC facilities : Available and upcoming technologies

Racsi, Bogdan Radu

January 2023

The aluminium industry is anticipated to witness a surge in demand, with projectionsof a two to three-fold increase by 2050. Meeting environmental objectives andaddressing the growing emphasis on sustainability from both the industry andconsumers seeking eco-friendly products present significant challenges. Energyefficiency will be crucial in addressing these concerns. While primary aluminiumproduction consumes the majority of energy in the industry, the die-casting sector, asan energy-intensive segment, offers opportunities for enhancing energy efficiency. Inhousealuminium smelting in high-pressure die-casting (HPDC) foundries, primarilyemploying gas-fired shaft furnaces with preheating for improved energy efficiency, isa significant energy user.This research examines energy efficiency in High-Pressure Die Casting (HPDC)foundries, particularly in-house aluminium smelting. Utilizing literature reviewsand expert interviews, the study reveals efficient technologies, drivers and barriersto energy efficiency, and the importance of sustainability. The current absence ofwell-defined Best Available Techniques (BAT) and the absence of validated claims bymanufacturers in the HPDC sector emphasize the urgent need for extensive researchand empirical verification.The results from this study show that using gas-fired shaft furnaces is the optimalchoice for the next decade, with waste heat recovery as the primary energy efficiencymethod, supplemented by the implementation of energy management systems andstrategies. Induction furnaces may emerge as a viable future technology, contingenton significant electricity network expansion and low energy prices.

high pressure die casting

HPDC

energy efficiency

cast house remelting

internal aluminium scrap

melting furnace

melting and holding furnace

drivers

barriers

Energy Systems

Energisystem