A CONTRIBUTION TO THE THEORY AND THE DEVELOPMENT OF REPAIRING GRAY CAST IRON COMPONENTS CONTAINING SURFACE DEFECT
Repair of the gray cast iron component containing surface defect is often necessary in many industries. The well established methods for repairing that component are Flame Spray and Shielded Metal Arc Welding (SMAW). However, the gray cast iron is very difficult to repair by welding due to the f...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/11004 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Repair of the gray cast iron component containing surface defect is often
necessary in many industries. The well established methods for repairing that
component are Flame Spray and Shielded Metal Arc Welding (SMAW).
However, the gray cast iron is very difficult to repair by welding due to the
formation of brittle white cast iron along with the occurrence of micro-cracks
(fissures). Welding process is also consumes long exposure time at high
temperature, leading to graphite coarsening and high residual stress near the
repaired defect. The combination of white cast iron, fissures and other lacks
mentioned above will lead to the failure on the component in the vicinity of the
repaired defect. Many efforts have been made to use other methods which are
Ultrasonic Insert Casting, Diffusion Bonding, and Impact-Electric Current
Discharge Joining. Nevertheless, these methods have not been yielding a
satisfying solution due to a relatively low repaired strength. They are also
impractical, costly, and inapplicable for the large components having variation of
defects dimensions and geometries.
From the economic point of view, repair process will decrease production cost at a
significant level. The repair cost much cheaper compared to the new imported
component which is very expensive. Based on the industrial data, the components
to be repaired are numerous. For example, one of the industries has 52 cylinder
heads to be repaired during months of April and May 2004. Therefore, a study
concerning the theory and the development of repairing gray cast iron containing
surface defects should be performed to overcome the existing repair problem.
The aim of this research is to develop know how in repairing gray cast iron to
overcome the weaknesses of the well established welding processes. The target of
the repaired know how is to get an excellent metallurgical bonding in the area of
the repaired defect that is free of white cast iron. The development of new method
is relied on the hypothesis that if the repair is performed by pouring the molten
metal into the surface defects with high enough heat input to locally melt the
surface, hence the joining will occur at controlled cooling rate in order to get
white cast iron free structures.
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The approached in the problem solution is performed by experiments, dimensional
analysis and numerical analysis based on computer solution. The experimental
approach is focused on creating some ideas translated into the design alternatives
(conceptualization). The next step is to examine the design alternatives to get a
potential method to fulfill the objective criteria on this research. The numerical
approach is aimed to simulate the physical phenomena during repair that occur on
the area of the repaired defect and to yield a number of new data as complement
to the experiment results. Dimensional analysis approach is used to build a
mathematical formulation as a generalization of the new method.
Four methods of repairing have been developed i.e. Pouring, Powder Filling,
Droplet Spray and Turbulence Flow Casting (TFC). TFC method has been proven
to the objective of this research. Joining occurs as a result of convection heat
transfer of molten flow into the sand mold which melts the existing base metal
inside the mold and subsequent solidification. The experiment results proved that
the metallurgical bonding at the joint was excellent since the fracture location
occur at the weld pool where the tensile strength was about 200 MPa. TFC
method, as a new repair solution, is powerful since the joint area after repair
process is free of cracks and brittleness. The utilization of TFC can minimize the
cooling rate, preventing the formation of the undesirable white cast iron.
Moreover, the homogeneity in properties at the area of repaired was back to the
original characteristics or like new. Through the appropriate selection of
parameters, TFC method can be able to repair defects without resulting in the
presence of white cast iron, martensite, cracks and porosities. However, the
parameters can only be applied to a certain defect dimension so that it has limited
application. In order to overcome this limitation, determination of parameters is
approached by the mathematical formulation representing generalization of TFC
process. Therefore, the formulation can be applied to the various defect
dimensions as long as it fulfills the similarity principle. In this work, the similarity
principle is used for Reynolds and Prandtl numbers of 11,100 and 0.14
respectively and the similarity of geometry is in the form of cylindrical channel.
Preheat to the component is a dominant factor repair process by TFC method. For
the large component (more than 500 mm thick), the preheating may be done by
stove, molten metal, heating coil or some other methods or even a combination of
them all. Nevertheless, the main idea for successful repair in TFC is such that the
preheating should provide a sufficient heat input to get a low cooling rate in the
vicinity of the repaired defect.
Mathematical Formulation resulted from the dimensional analysis approach can
be related to the other material such as stainless steel and aluminum alloys. Repair
method developed in this work represents a new breakthrough having contribution
to the manufacturing technology. Therefore, it can be proposed to make
standardization especially in repairing grey cast iron components containing
surface defect |
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