Importance of Thermal Conductivity of Soil in Construction Industry

Soil is one of the three major natural resources, alongside air and water. Soils are complex mixtures of minerals, water, air, organic matter, and countless organisms that are the decaying remains of once-living things. It serves as a natural medium for the plant growth.

Soil plays a major role in determining the depth of the foundation required to keep a building safe. Soil sometimes contains water which causes troubles in construction of foundation. Soil testing is extremely important to environmentally sensitive applications in agricultural and constructional fields. In the construction industry, buried cables and pipelines pose as possible threats. When construction companies are building underground systems, they must pay close attention to the moisture density and thermal conductive properties of the surrounding soil. If a low soil thermal conductivity is noted, cables and pipelines may experience overheating and may potentially combust.

Soil Testing Equipment

Using a soil testing equipment, you can measure the thermal property of a potential back-fill materials critical for optimizing internal temperature for buried pipes and electrical lines. One of the wide selection of thermal conductivity equipment is the TLS-100 soil conductivity meter developed by Thermtest. It is used to measure thermal conductivity and thermal resistivity. Perfect for testing soils, polymers, viscous liquids, and other soft materials.

Soil Mechanics

Soil Mechanics is a discipline of Civil Engineering involving the study of soil, its behaviour and application as an engineering material. The first scientific study of soil mechanics was undertaken by French physicist Charles-Augustin de Coulomb. He published a theory of earth pressure in 1773.


Reference:

https://thermtest.com/soil-testing-equipment
https://www.britannica.com/science/soil-mechanics

Thermal Conductivity - An Overview

What is Thermal Conductivity?

Thermal Conductivity can be defined as the ability of a material to transfer heat. The term conductivity refers to specified material that conducts electricity. It is evaluated primarily based on Fourier's Law of Heat Conduction. Heat Conduction or Thermal Conduction is the transfer of heat by microscopic collisions of particles and movement of electrons within a body. This general physical law is derived from empirical observations by J. Fourier, who expressed it first in his heat transfer text in 1822.

The general equation or formula of thermal conductivity is:

Where:

k is thermal conductivity in W/(m⋅K),
Q is amount of heat transfer through the material in J/S or W,
A is the area of the body in m2,
ΔT is difference in temperature in K. (T2 - T1)

As per the equation above, the thermal conductivity of material depends upon the following temperature gradient.

1. Density of material
2. Pressure and temperature
3. Material structure
4. Moisture content

In other words, higher the thermal conductivity of material, the rate of transfer heat through the material will be fast.

Units of Thermal Conductivity

In the International System of Units (SI), thermal conductivity is measured in watts per meter-kelvin (W/(m⋅K)). 

Thermal Conductivity Measurement

There are a number of possible ways to measure thermal conductivity, each of them suitable for a limited range of materials, depending on the thermal properties and the medium temperature. Some of the possible ways to measure thermal conductivity are the following:

1. Using the Heat Flow Meter Method

The Heat Flow Meter method is an easy-to-use rapid technique for thermal conductivity measurement and thermal resistance measurement of insulation products, construction materials, packaging, and assemblies. A measurement of thermal conductivity is an indicator of the ability of a material to conduct heat and can be critical for defining energy efficiency and thermal performance in materials.

2. Transient Methods

The transient methods perform a measurement during the process of heating up. The advantage is that measurements can be made relatively quickly. Transient methods are usually carried out by needle probes. 

Transient Plane Source Method

Transient Plane Source Method, utilizing a plane sensor and a special mathematical model describing the heat conductivity, combined with electronics, enables the method to be used to measure Thermal Transport Properties. This non-destructive method has a thermal conductivity testing range of 0.005 to 1800 W/(m⋅K) and can be used to measure bulk properties of homogeneous and heterogeneous materials, as well as directional properties for anisotropic materials. One of the thermal conductivity analyzer uses this method is the Hot Disk Transient Plane Source. The Hot Disk TPS is widely used for the accurate measurement of absolute thermal conductivity, thermal diffusivity, and specific heat of solids, liquids, pastes, and powders. 

TPS sensor

Transient Line Source Method

The Transient Line Source (TLS) follows ASTM D5334. The sensor needle consists of a thin heating wire and temperature sensor sealed in a 100 or 50 mm steel tube. The sensor is completely inserted into the sample to be tested. Heat is delivered to the sample using a constant current source (q) and the temperature rise is recorded over a defined period of time. The slope (a) from a plot of temperature rise versus the logarithm of time is used in the calculation of thermal conductivity (k). The higher the thermal conductivity of a sample, the lower the slope.

Series of needle probes used for transient line source measurements

3. Laser Flash Method

Laser Flash Method is a high-intensity laser that had the ability to measure thermal conductivity, thermal diffusivity, and specific heat capacity. An energy pulse heats one side of a plane-parallel sample and the resulting time dependant temperature rise on the backside due to the energy input is detected. Unlike other methods on the market, Laser Flash cannot measure thermal conductivity directly without calibration. It is determined by the shape of the temperature versus time curve at the rear surface.

Figure 1. Laser pulsation through sample material

References:

1. https://en.wikipedia.org/wiki/Thermal_conductivity

2. https://en.wikipedia.org/wiki/Thermal_conductivity_measurement

3. https://thermtest.com/what-is-thermal-conductivity

4. https://thermtest.com/history-3-laser-flash-method