Boron Grain Refinement: Part Two


Grain refinement using inoculents such as boron increase the nucleation sites within the material and there for lead to improvements in the overall durability of the material.
As well as reducing quality issues such as hot tearing, boron also provides enhancements to some key properties such as electrical and heat conductivity.

Inoculation is the introduction of a second phase particle into the melt in order to enhance grain refinement or modification. In grain refinement, the role of inoculants is to increase the number of nucleation sites and for them to be a catalyst during the early stages of solidification.

Grain refinement provides an equiaxed grain structure, uniform mechanical properties, and better machinability. It also eliminates shrinkage, increases resistance to hot tearing and improves feeding.

Cibula and subsequent researchers established the effectiveness of grain refinement through the addition of master alloys containing TiC or TiB2 nucleating agents. Such master alloys release insoluble TiC and TiB2 particles in the melt. These particles are potent inoculants for aluminum melt and form very fine grains. However, some undesirable attributes have been noticed in this practice.

When grain refining using Ti-B master alloys, TiB2 particles tend to settle down or agglomerate into clusters after they are added into the melt. Although the agglomeration tendency of TiC particles in TiC is much lower, it still presents a problem. In addition, it has been noticed that borides present in the Ti-B master alloy are associated with residual K2TiF6 and KBF6 salt, which comes from the manufacturing process of these master alloys.

As mentioned above, chemical grain refiners based on Al-Ti-B are widely used in aluminum casthouses and foundries worldwide. They are a key part in improving casthouse productivity, allowing faster DC ingot casting speeds, resistance to hot-cracking, as well as improving surface finish and mechanical properties.

The focus of the work Dr. Andreas Kleine, Dr. Macel Rosefort, Christina Matthies, Dr. Hubert Koch, and A.Pithan was to develop of new materials with improved properties of aluminum cast alloys.

A boron melt treatment is used for increasing the electrical and heat conductivity. This effect is caused by the removal of elements like titanium, zirconium etc. Additionally boron should work as a grain refiner instead of TiB2. Hence a better grain structure with improved mechanical properties was expected.

All castings, which were carried out for this investigation, are separately casted test bars with the following parameters:

  • Alloy AlSi7Mg
  • Mould material: gray iron
  • Mould temperature 370°C
  • Melt temperature 700-720°C
  • Cooling conditions air cooling
  • Heat treatment T6

Stated below the outstanding results of this investigation can be seen. The grain refinement of the boron addition can be seen in Figure 1. In comparison to the TiB2 refined alloy the boron refined alloy yields a much finer grain structure.

Figure 1: Examples for the grain structure of an GK-AlSi7Mg T6 a) with TiB2 grain refinement; b) with boron. All specimens are separately casted test bars

The optimized microstructure results in significantly better mechanical properties. While the yield strength is nearly the same, the UTS has increased. But the greatest effect could be observed in the ductility. The doubling of the elongation in comparison to the TiB2 refined material is a great benefit for multiple applications.

Table 1: Mechanical properties and grain sizes of the investigated specimens. All data are average values.

The second main aspect in this investigation was to improve the conductivity. The well-known advantages of the boron melt treatment could be confirmed. As well as the electrical conductivity, the heat conductivity could also be increased significantly, Figure 2. For example the heat conductivity is increased at RT from 178W/Km to 203W/Km. This means an overall increase of more than 14%.

Figure 2: Improvement of the heat and electrical conductivity of the boron grain refined AlSi7Mg in comparison to the AlSi7Mg with TiB2


1. N.Alem, Figueredo, D.Apelian: Novel methods for grain refining aluminium alloys,

2. Lakhwinder Singh, Geetesh Goga, Rupinderpreet Singh: Review of the latest developments in Grain refinement, International Journal of Modern Engineering Research (IJMER), Vol.2, Issue.4, July-Aug. 2012 pp-2724-2727 ISSN: 2249-6645

3. Dr. Andreas Kleine, Dr. Macel Rosefort, Christina Matthies, Dr. Hubert Koch, A.Pithan: Improved properties of aluminium cast alloys due to a boron grain refinement, TRIMET Aluminium AG, Essen, Germany,

기술 자료 검색

검색할 어구를 입력하십시오:

검색 범위



Total Materia는 다양한 나라와 규격에 따른 금속학 이미지에 대한 정보를 포함하고 있습니다.

메뉴 표시줄에 특별히 디자인된 금속학 탭을 이용하여, 금속학 데이터가 포함된 관심 재질을 리스트에서 선택하실 수 있습니다.

또한 금속학 데이터는 표준 빠른 검색을 통해 찾을 수 있으며 규격 내 소그룹 페이지를 통해 이용 가능한 관련 자료들이 표시됩니다.

재질명을 '재질'창에 입력하신 후 규격을 알고 계신다면 규격을 선택하고 '검색' 버튼을 클릭합니다.

미세 구조에 대한 일반적인 정보가 관련 관심 재질의 화학 조성과 함께 출력됩니다.

구조의 세부 범위를 보여주는 여러 배율에서의 이미지가 가능하다면 제공됩니다.

다양한 조건을 선택할 수 있으며, '조건 선택' 메뉴를 사용하여 다양한 공정 및 열처리에 따른 금속학 이미지를 보여줍니다.

Total Materia 데이터베이스를 사용해 보실 수 있는 기회가 있습니다. 저희는 Total Materia 무료 체험을 통해 150,000명 이상의 사용자가 이용하고 있는 커뮤니티로 귀하를 초대합니다.