After reading this article you will learn about:- 1. Process of Thermit Welding 2. Operation of Thermit Welding 3. Application and Uses 4. Advantages 5. Disadvantages.
Process of Thermit Welding:
- Shrinkage defects, mold material defects, pouring metal defects,. Metallurgical defects. As further examples of some of the reasons discontinuities and defects in metals the processing of iron ore to make still is shown in the following slides. Imagine the many places that discontinuities and defects could be generated in this process.
- Welding cracks are normally found in the weld metal, parent metal or the Heat Affected one. Welding Defect cracks can be of various types like: Longitudinal. Crater (found only in the weld metal) Branching. Welding defect cracks can be of various shapes and sizes and may appear on the surface or at any depth or even at.
On the shrinkage of metals and its effect in solidification processing Anders Lagerstedt Casting of Metals Royal Institute of Technology, KTH SE-100 44 Stockholm, Sweden Abstract The shrinkage during solidification of aluminium and iron based alloys has been studied experimentally and theoretically. The determined shrinkage behaviour has.
Thermit welding is a chemical welding process in which an exothermic chemical reaction is used to supply the essential heat energy. That reaction involves the burning of Thermit, which is a mixture of fine aluminum powder and iron oxide in the ratio of about 1:3 by weight.
Although a temperature of 3000°C may be attained as a result of the reaction, preheating of the Thermit mixture up to about 1300°C is essential in order to start the reaction.
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The mixture reacts according to the chemical reaction:
8 Al + 3 Fe3O4 → 9 Fe + 4 Al2O3 + heat (3000˚C, 35 kJ/kg of mixture)
Aluminum has greater affinity to react with oxygen; it reacts with ferric oxide to liberate pure iron and slag of aluminum oxide. Aluminum oxide floats on top of molten metal pool in the form of slag and pure iron (steel) settled below, because of large difference in densities.
Operation of Thermit Welding:
Thermit welding process is essentially a casting and foundry process, where the metal obtained by the Thermit reaction is poured into the refractory cavity made around the joint.
The various steps involved in Thermit welding are:
1. The two pieces of metal to be joined are properly cleaned and the edge is prepared.
2. Then the wax is poured into the joint so that a wax pattern is formed where the weld is to be obtained.
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3. A moulding box is kept around the joint and refractory sand is packed carefully around the wax pattern as shown in Fig. 7.40, providing the necessary pouring basin, sprue, and riser and gating system.
4. A bottom opening is provided to run off the molten wax. The wax is melted through this opening which is also used to preheat the joint. This makes it ready for welding.
5. The Thermit is mixed in a crucible which is made of refractory material that can withstand the extreme high heat and pressure, produced during the chemical reaction.
6. The igniter (normally barium peroxide or magnesium) is placed on top of the mixture and is lighted with a red hot metal rod or magnesium ribbon.
7. The reaction takes about 30 seconds and highly super-heated molten iron is allowed to flow into the prepared mould cavity around the part to be welded.
8. The super-heated molten metal fuses the parent metal and solidifies into a strong homogeneous weld.
9. The weld joint is allowed to cool slowly.
There are different Thermit mixtures available for welding different metals, such as copper and chromium. They use different metal oxides in place of ferrous oxide. Some typical Thermit mixture reactions with their temperature obtained are given below:
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3 CuO + 2 Al → 3Cu + Al2O3 + Heat (4860°C, 275 Kcal)
Cr2O3 + 2Al → 2Cr + Al2O3 + Heat (3000°C, 540 Kcal)
Application and Uses of Thermit Welding:
Thermit welding is a very old process and now-a-days, in most cases, it is replaced by electro-slag welding. However, this process is still in use.
Some applications are:
(i) Thermit welding is traditionally used for the welding of very thick and heavy plates.
(ii) Thermit welding is used in joining rail roads, pipes and thick steel sections.
(iii) Thermit welding is also used in repairing heavy castings and gears.
(iv) Thermit welding is suitable to weld large sections such as locomotive rails, ship hulls etc.
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(v) Thermit welding is used for welding cables made of copper.
Advantages of Thermit Welding:
1. Thermit welding is a simple and fast process of joining similar or dissimilar metals.
2. This process is cheap, as no costly power supply is required.
3. This process can be used at the places where power supply is not available.
Disadvantages of Thermit Welding:
1. Thermit welding is essentially used for ferrous metal parts of heavy sections.
2. It is uneconomical for welding cheap metals and light parts.
Related Articles:
When castings have openings, cavities, porous sections, and similar defects on the internal or external surface, it is often called porosity. It is generally due to shrinkage or gas as the casting cools. Both are caused by very different sources. Identifying and eliminating the source can be a challenge.
First, it is important to note that casting shrinkage and gas defects are part of foundry cast materials. A casting is an economic preform, a rough form based on the specifications of the drawing and purchase order. The rough form will always have minor levels of porosity.
Shrinkage Cavity Welding Equipment
Examples of Porosity in Castings
Liquid penetrant testing displaying gas (left), Radiographic testing displaying shrinkage (right)
Shrinkage Cavity Welding Definition
Stainless Foundry & Engineering (SF&E) evaluates all casting surfaces to the MSS SP-55 or ASTM A802 quality standards, both of which allow for some levels of acceptable shrinkage and gas. Understanding and controlling the process allows SF&E to continue to manufacture high integrity castings with above-average industry lead times.
Shrinkage Cavity Welding Techniques
In the following, SF&E engineers share how they investigate the reasons why shrinkage and gas defects exist, their different types, and how we have worked to eliminate them.