The maximum temperature that can be achieved
in blast furnace is :
- upto 1200 K
- upto 2200 K
- upto 1900 K
- upto 5000 K
The Correct Option is B
Solution and Explanation
To solve this question, we need to understand the maximum temperature that can be achieved in a blast furnace during its operation, which is a key aspect of metallurgy and steel manufacturing processes.
Blast furnaces are used primarily for smelting iron from iron ore and have been a cornerstone in the production of steel. The temperature within a blast furnace is a significant factor that affects the efficiency of the smelting process. Here is the step-by-step explanation:
- The maximum temperature achievable in a blast furnace is predominantly found in the lower region called the "hearth." This is where the molten iron accumulates.
- In a typical blast furnace, the maximum temperatures can reach up to approximately 2200 \, \text{K}. This is achieved through the combustion of coke in the presence of heated air blast.
- This high temperature is required to melt the iron ore and reduce it to molten iron.
Let's analyze the options:
- Upto 1200 K: This is far too low for the efficient operation of a blast furnace.
- Upto 2200 K: This is the correct option as it matches the known maximum operating temperature of a blast furnace.
- Upto 1900 K: While this temperature might be sufficient for some metallurgical processes, it does not represent the upper operational limits of a blast furnace.
- Upto 5000 K: This temperature is unrealistically high for any industrial furnace operation and well beyond current metallurgical technology.
Conclusion: The correct answer is that the maximum temperature that can be achieved in a blast furnace is upto 2200 K.
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Concepts Used:
Thermodynamics
Thermodynamics in physics is a branch that deals with heat, work and temperature, and their relation to energy, radiation and physical properties of matter.
Important Terms
System
A thermodynamic system is a specific portion of matter with a definite boundary on which our attention is focused. The system boundary may be real or imaginary, fixed or deformable.
There are three types of systems:
- Isolated System – An isolated system cannot exchange both energy and mass with its surroundings. The universe is considered an isolated system.
- Closed System – Across the boundary of the closed system, the transfer of energy takes place but the transfer of mass doesn’t take place. Refrigerators and compression of gas in the piston-cylinder assembly are examples of closed systems.
- Open System – In an open system, the mass and energy both may be transferred between the system and surroundings. A steam turbine is an example of an open system.
Thermodynamic Process
A system undergoes a thermodynamic process when there is some energetic change within the system that is associated with changes in pressure, volume and internal energy.
There are four types of thermodynamic process that have their unique properties, and they are:
- Adiabatic Process – A process in which no heat transfer takes place.
- Isochoric Process – A thermodynamic process taking place at constant volume is known as the isochoric process.
- Isobaric Process – A process in which no change in pressure occurs.
- Isothermal Process – A process in which no change in temperature occurs.
Laws of Thermodynamics
Zeroth Law of Thermodynamics
The Zeroth law of thermodynamics states that if two bodies are individually in equilibrium with a separate third body, then the first two bodies are also in thermal equilibrium with each other.
First Law of Thermodynamics
The First law of thermodynamics is a version of the law of conservation of energy, adapted for thermodynamic processes, distinguishing three kinds of transfer of energy, as heat, as thermodynamic work, and as energy associated with matter transfer, and relating them to a function of a body's state, called internal energy.
Second Law of Thermodynamics
The Second law of thermodynamics is a physical law of thermodynamics about heat and loss in its conversion.
Third Law of Thermodynamics
Third law of thermodynamics states, regarding the properties of closed systems in thermodynamic equilibrium: The entropy of a system approaches a constant value when its temperature approaches absolute zero.