Design & Analysis Of Disc Brake By Using Aluminium Matrix Composite

Design & Analysis Of Disc Brake By Using Aluminium Matrix Composite

Mayur D Sandbhor 1, Swaraj R Patil2, Bhaskar P More3 Harshada S Sawant 4
Prof. Mr. Nilesh Shinde 5

1 Student Of Mechanical Engineering & Datta Meghe College Of Engineering, Airoli, Navi Mumbai

2 Student Of Mechanical Engineering & Datta Meghe College Of Engineering, Airoli, Navi Mumbai

3 Student Of Mechanical Engineering & Datta Meghe College Of Engineering, Airoli, Navi Mumbai

4 Student Of Mechanical Engineering & Datta Meghe College Of Engineering, Airoli, Navi Mumbai

5 Assistant Professor Of Mechanical Engineering & Datta Meghe College Of Engineering, Airoli, Navi Mumbai

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Abstract - Metal Matrix Composites (MMCs) have shown great interest in recent times due to its potential of applications in aerospace and automotive industries because of having superior strength to weight ratio. The wide use of particular metal matrix composites for engineering applications has been obstructed by the exact use of silicon carbide (SiC) by weight %, hence high cost of components. Although there are several technical used for casting technology rather it can be used to overcome this problem. Materials are frequently chosen for structural applications because they have desirable combinations of mechanical characteristics. Development of hybrid metal matrix composites has become an important area of research interest in Materials Science. In view of this, the present study focuses on the behavior of aluminium silicon carbide (AL Sic) hybrid metal matrix composites.

An automotive brake disc or rotor is a device for slowing or stopping the motion of a wheel while it runs at a certain speed. The widely used brake rotor material is cast iron which consumes much fuel due to its high specific gravity. The aim of this paper is to develop the material selection method and select the optimum material for the application of brake disc system emphasizing on the substitution of this cast iron by any other lightweight material. Two methods are introduced for the selection of materials, such as cost per unit property and digital logic methods. Material performance requirements were analysed and alternative solutions were evaluated among cast iron, aluminium alloy, titanium alloy, ceramics and composites. Mechanical properties including compressive strength, friction coefficient, wear resistance, thermal conductivity and specific gravity as well as cost, were used as the key parameters in the material selection stages. The analysis led to aluminium metal matrix composite as the most appropriate material for brake disc system.

The suitable material for the braking operation is selected and all the values obtained from the analysis are less than their allowable values. Hence the brake Disc design is safe based on the strength and rigidity criteria. By identifying the true design features, the extended service life and long-term stability is assured.

Key Words: Aluminium(Al), silicon carbide (SiC), Metal Matrix Composites (MMCs), Disc Brake,