What standards does your soil mechanics laboratory follow?

Our laboratory operates in accordance with British Standards (BS 1377) and Eurocode 7. All testing procedures are accredited under ISO 17025, ensuring compliance with UK regulatory requirements for geotechnical investigations.

How long does a typical soil testing program take?

Standard classification tests such as granulometry and Atterberg limits are completed within 5–7 working days. Advanced triaxial and consolidation tests may require 2–4 weeks, depending on the number of samples and drainage conditions.

Do you provide services for small-scale projects?

Yes, our firm supports projects of all sizes, from residential extensions to major infrastructure. We offer flexible sampling kits and remote consultation to accommodate smaller budgets while maintaining full technical rigor.

Soil Gravimetric Relationships Calculator

Phase relationships (solids, water, air) are the starting point of any geotechnical analysis. This calculator converts between unit weight (γ), dry unit weight (γd), water content (w), specific gravity of solids (Gs), void ratio (e), porosity (n) and degree of saturation (S). Useful for interpreting Proctor tests, in-situ density, consolidation, triaxial tests, and for verifying the actual compaction of a fill relative to the maximum laboratory density.

What are gravimetric relationships?

Soil is a mixture of three phases: solid particles, water and air. Gravimetric relationships express the proportions between them. Knowing any two variables from the set (γd, w, Gs, e, n, S) allows the other four to be calculated using exact identities. They are applied to interpret laboratory results, convert field density to relative compaction, analyse saturation below the water table, evaluate collapsibility in unsaturated soils, and as input to consolidation, liquefaction and permeability analyses.

Applied formulas

Dry unit weight: γd = γ / (1 + w)

Void ratio: e = (Gs × γw / γd) − 1

Porosity: n = e / (1 + e)

Degree of saturation: S = (w × Gs) / e

Saturated unit weight: γsat = γw × (Gs + e) / (1 + e)

Submerged unit weight: γ' = γsat − γw

Where γw = 9.81 kN/m³ (unit weight of water), typical Gs 2.65-2.75.

Calculation example

Input data — undisturbed sample, metropolitan area building
Parameter	Value
Unit weight (γ)	19.2 kN/m³
Water content (w)	18.5 %
Specific gravity (Gs)	2.70

First the dry unit weight: γd = 19.2 / (1 + 0.185) = 19.2 / 1.185 = 16.20 kN/m³. Then the void ratio: e = (2.70 × 9.81 / 16.20) − 1 = (26.49 / 16.20) − 1 = 1.635 − 1 = 0.635. Porosity is n = 0.635 / (1 + 0.635) = 0.388 or 38.8 %. Degree of saturation: S = (0.185 × 2.70) / 0.635 = 0.4995 / 0.635 = 0.787 or 78.7 %. Saturated unit weight γsat = 9.81 × (2.70 + 0.635) / 1.635 = 9.81 × 2.040 = 20.01 kN/m³, and submerged γ' = 20.01 − 9.81 = 10.20 kN/m³.

Result: γd = 16.20 kN/m³ · e = 0.64 · n = 38.8 % · S = 78.7 % · γsat = 20.0 kN/m³ · γ' = 10.2 kN/m³.

Interpretation of results

S = 78.7 % indicates a partially saturated soil, typical above the water table. With e = 0.64 it is of medium density (values 0.4-0.7 are common for sands and stiff clays). If that sample were below the water table, γ' = 10.2 kN/m³ should be used to calculate effective stresses. Saturation above 95 % and e above 1.0 indicate very loose or soft soil, with high compressibility and potential consolidation problems.

Reference standards

BS 1377-2 (+ BS EN ISO 17892-4) — Determination of specific gravity of solids (pycnometer)
BS 1377-2 (+ BS EN ISO 17892-4) — Determination of water content in the laboratory
BS 1377-2 (+ BS EN ISO 17892-4) — Density and unit weight of intact specimens
BS 1377-2 (+ BS EN ISO 17892-4) — Soil Mechanics Laboratory — Determination of water content
BS 1377-2 (+ BS EN ISO 17892-4) — Determination of density of solid particles

Frequently asked questions

When do I use γ and when γ submerged?

γ (or total unit weight) is used above the water table to calculate total stresses. Below the water table, γsat is used for total stresses and γ' = γsat − γw for effective stresses. Mixing them is a common error that overestimates or underestimates consolidation and bearing capacity calculations.

What typical Gs should I assume if I have no test?

For most granular soils and clays, Gs = 2.65 to 2.75. Pure siliceous sands 2.65; common clays 2.70-2.75; soils with high mica or organic content drop to 2.5-2.6; magnetite or heavy minerals can rise to 2.9 or more. If in doubt, measurement is mandatory.

Can I have S > 100 %?

No in a real soil. If the calculation gives S > 100 % it means there is a test error: overestimated water content, incorrect Gs, or underestimated void ratio. First check the measurement of w and Gs before accepting the result.

How do I go from compaction water content to the dry or wet side of the Proctor optimum?

With w and Gs you calculate e and S at that point. The dry side of the optimum typically has S between 70-85 % and the wet side between 85-95 %. On the Proctor curve, the "saturation line" (S = 100 %) is the theoretical upper limit and serves as a reference to verify that the curve is consistent.