Calculate compacted volume from loose material. Enter loose volume and compaction factor to estimate final compacted fill for earthwork projects.
When loose fill material is placed and compacted, it shrinks in volume. This shrinkage — the compaction factor — is critical for estimating how much loose material you need to achieve a specified compacted volume. Without accounting for compaction, you'll end up short on material and need costly additional deliveries.
The compaction factor varies by soil type. Sandy soils compact 5–10%, while clay soils can compact 15–25%. Properly compacted fill creates a stable, settlement-free base for foundations, slabs, and pavements. This calculator converts between loose and compacted volumes using the compaction factor specific to your material.
Contractors use this calculation daily to determine how many loose cubic yards of fill to order to achieve the design's compacted volume. Getting it right on the first truck saves time, money, and project delays.
Accurate calculation of this value helps construction professionals plan projects more effectively, reduce material waste, and ensure compliance with building codes and industry standards.
If you need 100 cubic yards of compacted fill in place, you need to order more than 100 cubic yards of loose material because it will shrink during compaction. This calculator tells you exactly how much loose material to order to achieve your target compacted volume. Consistent use of this tool across projects builds a library of reference data that improves estimating accuracy over time and reduces reliance on individual experience alone.
Compacted Volume = Loose Volume × Compaction Factor Loose Volume Needed = Compacted Volume ÷ Compaction Factor Volume Loss = Loose Volume − Compacted Volume
Result: 85 CY compacted from 100 CY loose
Starting with 100 cubic yards of loose fill and a compaction factor of 0.85, you'll end up with 85 compacted cubic yards. Conversely, if you need 100 CY compacted, you'd order 100 ÷ 0.85 = 117.65 CY of loose fill.
The compaction factor is the ratio of compacted volume to loose volume. It accounts for the reduction in air voids when force is applied to loose material. Different soils have different factors based on their grain structure, moisture content, and composition.
Sand and gravel compact 5–10% (factor 0.90–0.95). Silty soils compact 10–15% (factor 0.85–0.90). Clay compacts 15–25% (factor 0.75–0.85). Rock fill compacts 5–10%. These ranges assume proper moisture and mechanical compaction.
Proper compaction requires the right equipment, lift thickness, and moisture content. Compact granular soils (sand, gravel) with vibratory equipment. Compact cohesive soils (clay, silt) with sheepsfoot or padfoot rollers. Always test density during the work to ensure compliance.
The biggest mistakes are compacting lifts that are too thick, neglecting moisture control, and using the wrong type of compactor. Another common error is not testing — visual inspection alone cannot verify that required density has been achieved.
The compaction factor represents the ratio of compacted volume to loose volume. A factor of 0.85 means loose material compacts to 85% of its original volume. The remaining 15% is air space that gets squeezed out during compaction.
General fill dirt has a compaction factor of 0.85–0.90. Sandy fill is 0.90–0.95, clay fill is 0.75–0.85, and gravel is 0.90–0.95. These values assume proper moisture content and mechanical compaction.
Compaction factor measures shrinkage when placing and compacting fill. Swell factor measures expansion when excavating undisturbed soil. They are inverse concepts: swell happens when you dig, compaction happens when you fill.
Most building codes require 95% Standard Proctor density for structural fill under buildings and 90–95% for general fill. Roadway subgrade typically requires 95–98%. Your project specifications will state the exact requirement.
Common tests include the nuclear density gauge (fast, non-destructive), sand cone test (traditional, reliable), and drive cylinder method. Each test measures the in-place density and compares it to the maximum density from a Proctor test.
Yes, significantly. Every soil has an optimum moisture content at which maximum density is achieved. Too dry and particles won't consolidate. Too wet and water prevents full compaction. A Proctor test determines the optimum moisture.
Hand tamping works for small areas but won't achieve the level of compaction needed for structural applications. Use a plate compactor for granular soils and a jumping jack (trench) compactor or roller for cohesive soils.
Standard lift thickness is 6–8 inches (loose) for most compaction equipment. Thinner lifts (4–6 inches) produce better compaction. Never try to compact lifts thicker than 12 inches — the bottom won't reach adequate density.