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Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering PDF Download

Lecture 5 - Conduction: One Dimensional, Heat Transfer

Illustration 2.3
Consider a composite wall containing 5-different materials as shown in the fig. 2.7. Calculate the rate of heat flow through the composite from the following data?

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

Solution 2.3 
 Assumptions:

1. Steady-state one-dimensional conduction.
2. Thermal conductivity is constant for the temperature range of interest.
3. The heat loss through the edge side surface is insignificant.
4. The layers are in perfect thermal contact. 
5. Area in the direction of heat flow is 1 m2.

The height of the first layer is 4 m (h1 = h2 + h).
The equivalent circuit diagram of the above composite is,

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

On calculating equivalent resistance with the given data (Note: thickness of layer 2 = thickness of layer 3 and thickness of layer 4 = thickness of layer 5, in the heat flow direction),

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

 

Fig. 2.7: Composite of illustration 2.3; (a) composite, (b) corresponding electrical circuit

Thus the heat flow rate through the composite,

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

2.2 Thermal contact resistance
In the previous discussion, it was assumed that the different layers of the composite have perfect contact between any two layers. Therefore, the temperatures of the layers were taken same at the plane of contact. However, in reality it rarely happens, and the contacting surfaces are not in perfect contact or touch as shown in the fig.2.8(a). It is because as we know that due to the roughness of the surface, the solid surfaces are not perfectly smooth. Thus when the solid surfaces are contacted the discrete points of the surfaces are in contact and the voids are generally filled with the air. Therefore, the heat transfer across the composite is due to the parallel effect of conduction at solid contact points and by convection or probably by radiation (for high temperature) through the entrapped air. Thus an apparent temperature drop may be assumed to occur between the two solid surfaces as shown in the fig.2.8b. If TI and TII are the theoretical temperature of the plane interface, then the thermal contact resistance may be defined as,

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

where Rcrepresents the thermal contact resistance.

The utility of the thermal contact resistance (Rc ) is dependent upon the availability of the reliable data. The value of Rc depends upon the solids involved, the roughness factor, contact pressure, material occupying the void spaces, and temperature.  The surface roughness of a properly smooth metallic surface is in the order of micrometer. The values of Rc generally obtained by the experiments. However, there are certain theories which predict the effect of the various parameters on the Rc.

It can be seen in the fig.2.8, that the two main contributors to the heat transfer are (i) the conduction through entrapped gases in the void spaces and, (ii) the solid-solid conduction at the contact points. It may be noted that due to main contribution to the resistance will be through first factor because of low thermal conductivity of the gas.

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

Fig.2.8 (a) Contacting surfaces of two solids are not in perfect contact, (b) temperature drop due to imperfect contact

 

If we denote the void area in the joint by Av and contact area at the joint by Ac, then we may write heat flow across the joint as,

Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering
Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering

where, thickness of the void space and thermal conductivity of the fluid (or gas) is represented by lgand kf, respectively. It was assumed that lg/2 is the thickness of solid-I and solid-II for evenly rough surfaces.

The document Conduction: One Dimensional - 3 | Heat Transfer - Mechanical Engineering is a part of the Mechanical Engineering Course Heat Transfer.
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FAQs on Conduction: One Dimensional - 3 - Heat Transfer - Mechanical Engineering

1. What is one-dimensional conduction in chemical engineering?
Ans. One-dimensional conduction in chemical engineering refers to the transfer of heat within a material in a single direction. It occurs when there is a temperature gradient along a straight line, and the heat flows parallel to that line. This concept is commonly used to analyze heat transfer in pipes, rods, and other cylindrical or planar geometries.
2. How is one-dimensional conduction different from multi-dimensional conduction?
Ans. One-dimensional conduction is characterized by heat transfer occurring only in one direction, whereas multi-dimensional conduction involves heat transfer in multiple directions. In one-dimensional conduction, temperature gradients exist only along a single line, while in multi-dimensional conduction, temperature gradients can exist in multiple directions, such as radial or axial directions.
3. What factors affect the rate of one-dimensional conduction?
Ans. The rate of one-dimensional conduction is influenced by several factors, including the thermal conductivity of the material, the temperature difference across the material, the thickness of the material, and the surface area through which heat is being transferred. Additionally, the presence of any insulation or boundary conditions can also affect the rate of conduction.
4. How is one-dimensional conduction analyzed in chemical engineering?
Ans. In chemical engineering, one-dimensional conduction is often analyzed using Fourier's law of heat conduction. This law relates the rate of heat transfer through a material to the temperature gradient and the material's thermal conductivity. By solving the one-dimensional heat conduction equation, which is a partial differential equation, engineers can determine the temperature distribution and the heat transfer rate within the material.
5. What are some practical applications of one-dimensional conduction in chemical engineering?
Ans. One-dimensional conduction has several practical applications in chemical engineering. It is commonly used to analyze heat transfer in pipes, heat exchangers, and reactors. For example, understanding one-dimensional conduction is crucial for designing efficient heat exchangers that maximize heat transfer between two fluids. It is also important in the design of insulation materials to minimize heat loss in industrial processes.
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