Economics of aluminum

Gas savings in the production of extruded aluminium

It is known that the aluminum industry consumes huge amounts of natural gas. Therefore, in the current situation with global gas prices and shortages, it’s time to think about how to reduce its consumption. Is it possible gas saving in the production of extruded aluminium? Let’s try to do this using the example of the production of aluminum profiles from alloys of the 6xxx series.

Production of aluminum profiles from 6xxx alloys

During the manufacture of extruded aluminum profiles from 6xxx alloys, these alloys are subjected to a complex combination of thermal and thermomechanical processes. At each stage, changes in the structure of the alloy occure, including dissolution, precipitation or enlargement of particles of magnesium silicide (Mg2Si). These changes can positively or negatively affect the final mechanical properties of the finished profiles..

The profile production cycle includes (Figure 2):

  • Melting aluminum scrap or primary and secondary melting ingots
  • Casting of extrusion ingots (logs)
  • Homogenization of ingots
  • Heating of ingots (billets) before extrusion
  • Hot extrusion
  • Cooling (quenching) profiles at the outlet of the press
  • Thermal hardening (aging).

Figure 2 – Thermal and thermomechanical processes in the manufacture of extruded aluminum profiles from 6xxx alloys [1]

Gas consumption

Consider the consumption of natural gas on the example of a typical modern set of equipment for the production of aluminum profiles from aluminum scrap [2].

The total gas consumption per tonne of aluminum is 1135-1255 kW∙h,


  • Two-chamber melting furnace: 660-700
  • Casting (holding) furnace: 30-50
  • Homogenising furnace: 195-205
  • Billet heating furnace: 175-215
  • Ageing oven: 75-85

It is believed, that one cubic meter of natural gas is equivalent to 10,6 kW∙h [2].

Old equipment requires more gas

Note, that the above gas consumption figures refer to modern production, where all furnaces and thermal units are equipped with recovery and regeneration systems. This usually saves 15-20 % fuel. Therefore, if the equipment in your factory does not have these advanced technologies, then gas consumption will be higher, least, on those 15-20 %. At the same time, gas savings will be greater!

Where can you save gas?

The amount of heat, which must be introduced into aluminum during its melting or heating of the billet before extrusion is determined by the physical characteristics of aluminum, solid and liquid (Figure 3).


Figure 3 [3]

Regeneration and recovery

If the melting and holding furnace, as well as the billet heating furnace already have regeneration and recovery systems, then it is already difficult to reduce gas consumption on them. If these systems are missing, then this is a real opportunity to save gas. However, this equipment requires a significant investment..

Homogenization of extrusion ingots

Need to take into account, that the technological modes of homogenization of aluminum extrusion ingots were developed back in the 1970s. At that time, the cost of natural gas was much lower, than currently.

The process of homogenization of ingots from 6xxx alloy at a temperature 560-585 ºС usually passes within 5-10 hours.

Goals of homogenization (Figure 4):

  • Dissolve all Mg2Si in aluminum base (red line)
  • Convert iron particles from type β to type α (blue line).

Figure 4 [1]

Question #1:

  • How justified is the typical soaking of 6063 alloy ingots during 5-6 hours, and even 8 hours? According to Figure 4 the main homogenization processes take place for 2-3 hours.

Artificial aging of alloys 6xxx

6xxx alloys are typical heat-hardenable aluminum alloys.. It means, that they achieve their final strength through heat treatment, and not plastic (cold) deformation (work-hardening).

The main alloying elements of these alloys are magnesium (Mg) and silicon (Si), which form the compound Mg2Si in the form of particles in three main forms (Figure 3):

  • β“-Mg2Si – the smallest precipitates of Mg2Si. Have a rod shape. Give the maximum contribution to strength properties.
  • β`-Mg2Si – rod-shaped particles, but big size. Grow from particles of category β“. Give a minimal contribution to strength properties.
  • β Mg2Si – coarse Mg precipitates2Si. Have a cubic shape. Do not contribute to strength properties.

Figure 5 [1]

The strength of 6xxx series alloys is directly related to the ability of the material to resist the movement of dislocations during deformation.. These dislocations are formed and move through the material when stresses are applied to it.. With increasing stresses, the number and density of dislocations, that pass through the material, increase until then, until it collapses. The peak of mechanical properties is reached at the maximum distribution density of small particles β“Mg2Si.

Heating temperature and holding time

Final strength characteristics, for example, alloy 6063 as a result of artificial aging, it strongly depends on the temperature in the furnace and the duration (Figure 5):

  • The higher the temperature, the faster peak strength is reached
  • The higher the temperature, the lower the strength
  • At temperatures above 170 ºС peak strength is practically not reached.

Figure 6 [4]

Question #2:

  • Isn’t it time to apply the modes of artificial aging with a shorter cycle?

Economic technology

In the current situation with a sharp rise in the price of natural gas, it is urgent to look for ways to reduce its consumption, including, in case of production of extruded aluminum profiles. Technologies currently in use have been developed, when natural gas was very cheap. Therefore, the technological parameters and technical requirements used today may well be excessive.. They need to be analyzed and revised taking into account modern economic realities.

  • Any high quality product must be economically justified.


  1. Basic Metallurgy 6000 series Extrusion Alloys, Comalco Publication
  2. Energy-optimised route from aluminium scrap to extruded semi-finished products /G. Valder and H. Pfeifer – Otto Junker – 2014
  3. Direct Charged Melter / D. F. Whipple – 2004
  4. Precipitatation Aging / R.W. Hains, Alcan Canada Products, Ltd. – Extrusion Technology Seminar 1977