# How To Calculate The Bearing Capacity Of Soils

The **bearing capacity of soil** is given by the equation

\(Q_a=\frac{Q_u}{FS}\)

in which _Q_{a}_ is the allowable bearing capacity (in kN/m^{2} or lb/ft^{2}), _Q_{u}_ is the ultimate bearing capacity (in kN/m^{2} or lb/ft^{2}) and FS is the safety factor. The ultimate bearing capacity _Q_{u}_ is the theoretical limit of the bearing capacity.

Much like how the Leaning Tower of Pisa leans due to the deformation of soil, engineers use these calculations when determining the weight of buildings and houses. As engineers and researchers lay down foundation, they need to make sure their projects are ideal for the ground that supports it. Bearing capacity is one method of measuring this strength. Researchers can calculate the bearing capacity of soil by determining the limit of contact pressure between the soil and the material placed on it.

These calculations and measurements are performed on projects involving bridge foundations, retaining walls, dams and pipelines that run underground. They rely on the physics of soil by studying the nature of the differences caused by pore water pressure of the material underlying the foundation and the inter-granular effective stress between the soil particles themselves. They also depend upon fluid mechanics of the spaces between soil particles. This accounts for cracking, seepage and the shear strength of the soil itself.

The following sections go into greater detail on these calculations and their uses.

## Formula for Bearing Capacity of Soil

Shallow foundations include strip footings, square footings and circular footings. The depth is usually 3 meters and allow for cheaper, more feasible and more easily transferable results.

**Terzaghi Ultimate Bearing Capacity Theory** dictates that you can calculate the ultimate bearing capacity for shallow continuous foundations _Q_{u}_ with

\(Q_u=cN_c+gDN_q+0.5gBN_g\)

in which *c* is the cohesion of soil (in kN/m^{2} or lb/ft^{2}), *g* is the effective unit weight of soil (in kN/m^{3} or lb/ft^{3}), *D* is the depth of footing (in m or ft) and B is the width of the footing (in m or ft).

For shallow square foundations, the equation is _Q_{u}_ with

\(Q_u=1.3cN_c+gDN_q+0.4gBN_g\)

and, for shallow circular foundations, the equation is

\(Q_u=1.3cN_c+gDN_q+0.3gBN_g\)

In some variations, the g is replaced with *γ*.

The other variables depend upon other calculations. _N_{q}_ is

\(N_q=\frac{e^{2\pi (0.75-\phi '/360)\tan{\phi '}}}{2\cos{(2(45+\phi '/2))}}\)

_N_{c}* is 5.14 for *ф'=0_ and

\(N_C=\frac{N_q-1}{\tan{\phi '}}\)

for all other values of ф', *Ng* is:

\(N_g=\tan{\phi '}\frac{K_{pg}/\cos{2\phi '}-1}{2}\)

_K_{pg}* is obtained from graphing the quantities and determining which value of *K_{pg}* accounts for the trends observed. Some use *N_{g} = 2(N_{q}+1)tanф'/(1+.4sin4**ф')* as an approximation without needing to calculate *K**pg._

There can be situations in which the soil shows signs of local **shear failure**. This means the soil strength cannot show enough strength for the foundation because the resistance between the particles in the material isn't great enough. In these situations, the square foundation's ultimate bearing capacity is _Q_{u} = .867c N_{c} + g D N_{q} + 0.4 g B N_{g} ,* the continuous foundation's i*s* Qu = 2/3c Nc + g D Nq + 0.5 g B Ng and the circular foundation's is *Q__{u} *= .867c N*_{c} *+ g D N*_{q} *+ 0.3 g B N*__{g}_.

## Methods of Determining Bearing Capacity of Soil

Deep foundations include pier foundations and caissons. The equation for calculating ultimate bearing capacity of this type of soil is is _Q_{u} = Q_{p} + Q_{f} *in which *Q_{u}_ is the ultimate bearing capacity (in kN/m^{2} or lb/ft^{2}), _Q_{p}_ is the theoretical bearing capacity for the tip of the foundation (in kN/m^{2} or lb/ft^{2}) and _Q_{f}_ is the theoretical bearing capacity due to shaft friction between the shaft and soil. This gives you another formula for bearing capacity of soil

You can calculate the theoretical end bearing (tip) capacity foundation _Q_{p}_ as _Q_{p} = A_{p}q_{p}* in which *Q_{p}_ is the theoretical bearing capacity for the end bearing (in kN/m^{2} or lb/ft^{2}) and _A_{p}_ is the effective area of the tip (in m^{2} or ft^{2}).

The theoretical unit tip-bearing capacity of cohesion-less silt soils _q_{p}* is *qDN_{q}* and, for cohesive soils, *9c,_ (both in kN/m^{2} or lb/ft^{2}). _D_{c}* is the critical depth for piles in loose silts or sands (in m or ft). This should be *10B* for loose silts and sands, *15B* for moderate density silts and sands and *20B_ for very dense silts and sands.

For the skin (shaft) friction capacity of pile foundation, the theoretical bearing capacity _Q_{f}* is *A_{f}q_{f}_ for a single homogeneous soil layer and _pSq_{f}L* for more than one layer of soil. In these equations, *A_{f} *is the effective surface area of the pile shaft, *q_{f}* is *kstan(d)_, the theoretical unit friction capacity for cohesion-less soils (in kN/m^{2} or lb/ft) in which *k* is the lateral earth pressure, *s* is the effective overburden pressure and *d* is the external friction angle (in degrees). *S* is the summation of differing soil layers (i.e. _a_{1}* + *a_{2}* + .... + *a_{n}_).

For silts, this theoretical capacity is *c*_{A} *+* *kstan(d)* in which _c_{A}* is the adhesion. It is equal to *c,* the cohesion of soil for rough concrete, rusty steel and corrugated metal. For smooth concrete, the value is *.8c* to *c*, and, for clean steel, it is *.5c* to *.9c*. *p* is the perimeter of the pile cross section (in m or ft). *L_ is the effective length of the pile (in m or ft).

For cohesive soils, *q*_{f} *= aS*_{u} in which a is the adhesion factor, measured as _1-.1(S_{uc})^{2}* for *S_{uc}_ less than 48 kN/m^{2} where _S_{uc} = 2c_ is the unconfined compression strength (in kN/m^{2} or lb/ft^{2}). For _S_{uc}* greater than this value, *a = [0.9 + 0.3(S_{uc} - 1)]/S_{uc}_.

## What is the Factor of Safety?

The safety factor ranges from 1 to 5 for various uses. This factor can account for magnitude of damages, relative change in the chances a project may fail, the soil data itself, tolerance construction and accuracy of design methods of analysis.

For instances of shear failure, the safety factor varies from 1.2 to 2.5. For dams and fills, the safety factor ranges from 1.2 to 1.6. For retaining walls, it's 1.5 to 2.0, for shear sheet piling, it's 1.2 to 1.6, for braced excavations, it's 1.2 to 1.5, for shear spread footings, the factor is 2 to 3, for mat footings it is 1.7 to 2.5. By contrast, instances of seepage failure, as materials seep through small holes in pipes or other materials, the safety factor ranges from 1.5 to 2.5 for uplift and 3 to 5 for piping.

Engineers also use rules of thumb for the safety factor as 1.5 for retaining walls that are overturned with granular backfill, 2.0 for cohesive backfill, 1.5 for walls with active earth pressure and 2.0 for those with passive earth pressures. These safety factors help engineers avoid shear and seepage failures as well as the soil may move as a result of the load bearings on it.

## Practical Calculations of Bearing Capacity

Armed with the test results, engineers calculate how much load the soil can safely bear. Beginning with the weight required to shear the soil, they add a safety factor so the structure never applies enough weight to deform the soil. They can adjust the footprint and depth of a foundation to stay within that value. Alternatively, they can compress the soil to increase its strength, by, for instance, using a roller to compact loose fill material for a roadbed.

Methods of determining bearing capacity of soil involve the maximum pressure that the foundation can exert onto the soil such that the acceptable safety factor against shear failure is below the foundation and the acceptable total and differential settlement are met.

The ultimate bearing capacity is the minimum pressure that would cause the shear failure of the supporting soil immediately below and adjacent to the foundation. They take into account the shear strength, density, permeability, internal friction and other factors when building structures on soil.

Engineers use their best judgement with these methods of determining bearing capacity of soil when performing many of these measurements and calculations. The effective length requires the engineer making a choice about where to start and stop measuring. As one method, the engineer may choose to use the pile depth and subtract any disturbed surface soils or mixtures of soils. The engineer may also choose to measure it as the length of a pile segment in a single soil layer of soil that consists of many layers.

## What Causes Soils to Become Stressed?

Engineers need to account for soils as mixtures of individuals particles that move around with respect to one another. These units of soils can be studied to understand the physics behind these movements when determining the weight, force and other quantities with respect to the buildings and projects engineers build upon them.

Shear failure can result from the stresses applied to soil that cause the particles to resist one another and disperse in ways that are detrimental to building. For this reason, engineers must be careful in choosing designs and soils with appropriate shear strengths.

The **Mohr Circle** can visualize the shear stresses on the planes relevant to building projects. The Mohr Circle of Stresses is used in geological research of soil testing. It involves using cylinder-shaped samples of soils such that the radial and axial stresses act on the layers of soils, calculated using planes. Researchers then use these calculations to determine the bearing capacity of soils in foundations.

## Classifying Soils by Composition

Researchers in physics and engineering can classify soils, sands and gravels by their size and chemical constituents. Engineers measure the specific surface area of these constituents as the ratio of the surface area of particles to the mass of the particles as one method of classifying them.

Quartz is the most common component of silt and sand and mica and feldspar are other common components. Clay minerals like montmorillonite, illite and kaolinite make up sheets or structures that are plate-like with large surface areas. These minerals have specific surface ares from 10 to 1,000 square meters per gram of solid.

This large surface area allows for chemical, electromagnetic and van der Waals interactions. These minerals can be very sensitive to the amount of fluid that may pass through their pores. Engineers and geophysicists can determine the types of clays present in various projects to calculate the effects of these forces to account for them in their equations.

Soils with high-activity clays can be very unstable because they are very sensitive to fluid. They swell in the presence of water and shrink in its absence. These forces can cause cracks in the physical foundation of buildings. On the other hand, materials that are low-activity clays that are formed under more stable activity can be much more easy to work with.

## Soil Bearing Capacity Chart

Geotechdata.info has a list of soil bearing capacity values you can use as a soil bearing capacity chart.

### Cite This Article

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Ather, S. Hussain. "How To Calculate The Bearing Capacity Of Soils" *sciencing.com*, https://www.sciencing.com/calculate-bearing-capacity-soils-5839061/. 27 December 2020.

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Ather, S. Hussain. How To Calculate The Bearing Capacity Of Soils last modified August 30, 2022. https://www.sciencing.com/calculate-bearing-capacity-soils-5839061/