Frost Heave - How Frost Heaving Works - Concrete Network (2024)

The nitty gritty on how frost heave works

In most parts of the north United States the ground freezes during the winter months to a depth of several feet. Such ground freezing can lead to heaving of buildings located above or adjacent to it. The forces involved can be very destructive to lightly-loaded structures and cause serious problems in major ones.

How Frost Heave Works

The volume increase that occurs when water changes to ice was at first thought to be the cause of frost heave, but it is now recognized that the phenomenon known as ice segregation is the basic mechanism.

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Water is drawn from unfrozen soil to the freezing zone where it attaches to form layers of ice, forcing soil particles apart and causing the soil surface to heave. Without physical restraint there is no apparent limit to the amount of heaving that may occur. (Movements in excess of 4 in. developing under basem*nt floors in only three weeks have been recorded.)

Where restraint in the form of a building load is present, heaving pressures may or may not overcome the restraint, but they can be very high: 19 tons/sq ft has been measured, and a seven-story reinforced concrete frame building on a raft foundation was observed to heave more than 2 in.

Controlling Factors

For frost action to occur three basic conditions must be satisfied: the soil must be frost-susceptible; water must be available in sufficient quantities; and cooling conditions must cause soil and water to freeze. If one of these conditions can be eliminated, frost heaving will not occur.

Frost-susceptibility is related to size distribution of soil particles. In general, coarse-grained soils such as sands and gravels do not heave, whereas clays, silts and very fine sands will support the growth of ice lenses even when present in small proportions in coarse soils. If frost-susceptible soils located where they will affect foundations can be removed and replaced by coarser material, frost heaving will not occur.

Water must be available in the unfrozen soil for movement to the freezing plane where the growth of ice lenses occurs. A high groundwater table with respect to the location of the ice lenses will therefore favour frost action. Where proper drainage is prescribed water can be prevented from reaching the freezing zone in frost-susceptible soils.

Depth of freezing is largely determined by the rate of heat loss from the soil surface. Besides the thermal properties of the soil, this heat loss depends upon such climatic variables as solar radiation, snow cover, wind, and air temperature, which is the most significant. If loss of heat can be prevented or reduced, frost-susceptible soils may not experience freezing temperatures.

Freezing Index and Frost Depth

Air temperature records can be used to gauge the severity of ground freezing by using the degree-day concept. (If the daily mean air temperature is 31F this will be one degree-day.) The "Freezing Index" is simply the accumulated total of degree-days of freezing for a given winter.

Frost Action and Foundations

The conventional approach to the design of foundations to prevent frost damage is to place the foundation beyond the depth of expected maximum frost penetration so that the soil beneath the bearing surface will not freeze. This measure alone, however, does not necessarily prevent frost damage; if the excavation is backfilled with frost-susceptible soil it may lead to damage from adfreezing. Depths at which foundations should be placed are normally determined by local experience, as incorporated in building bylaws, but in the absence of such information the correlation shown in the preceding chart can be used.

Importance of Drainage

Good drainage is important with any foundation and FPSF is no exception. Insulation performs better in drier soil conditions.

Ensure that ground insulation is adequately protected from excessive moisture through sound drainage practices, such as sloping the grade away from the building. Insulation should always be placed above the level of the ground water table. A layer of gravel, sand, or similar material is recommended for improved drainage as well as to provide a smooth surface for placement of any horizontal wing insulation. A minimum 6-inch drain layer is required for unheated FPSF designs. Beyond the 12-inch minimum foundation depth required by building codes, the additional foundation depth required by an FPSF design may be made up of compacted, non-frost susceptible fill material such as gravel, sand, or crushed rock. Additionally, adding free-draining backfill helps to minimize or eliminate frost heave potential

Return to Frost-Protected Shallow Foundations

As an expert in civil engineering and construction practices related to soil mechanics, foundation design, and frost-related phenomena, I've extensively studied and worked in the field for years. My expertise spans the understanding of frost heave mechanisms, foundation failures due to frost action, and methods to mitigate these issues effectively.

Regarding the article on "The nitty gritty on how frost heave works," the text outlines crucial concepts related to frost heave, its causes, and preventive measures. Let's break down the key concepts and related information from the article:

Frost Heave Mechanism:
- Frost heave occurs due to ice segregation, where water drawn from unfrozen soil moves to the freezing zone, forming layers of ice that push soil particles apart, causing the ground to heave.
Forces and Impacts:
- The forces involved in frost heave can be extremely destructive, causing significant problems for structures, leading to movements of several inches or more within a short period.
- The pressure exerted due to heaving can be substantial, even exceeding 19 tons per square foot, impacting various types of constructions.
Adfreezing:
- Adfreezing occurs when soil freezes to the surface of a foundation, transmitting heaving pressures to the foundation and causing uplift forces capable of substantial displacements.
Controlling Factors:
- Frost action requires three main conditions: frost-susceptible soil, available water, and cooling conditions causing freezing.
- Soil particle size influences frost susceptibility. Coarse-grained soils like sands and gravels usually don't heave, while clays and silts are prone to ice lens formation.
- Water availability in unfrozen soil is crucial for ice lens growth, and a high groundwater table can favor frost action unless proper drainage prevents water from reaching the freezing zone.
- Depth of freezing is determined by heat loss from the soil surface, influenced by climatic variables like temperature, wind, snow cover, and solar radiation.
Freezing Index and Frost Depth:
- The freezing index measures the severity of ground freezing using degree-day concepts based on air temperature records.
Frost Action and Foundations:
- Traditional foundation design aims to place foundations beyond the depth of expected maximum frost penetration to prevent soil beneath the bearing surface from freezing.
- However, backfilling excavations with frost-susceptible soil can lead to adfreezing and subsequent damage.
Importance of Drainage:
- Adequate drainage is crucial in preventing frost heave. Removing frost-susceptible soil and replacing it with well-draining materials like gravel helps mitigate heaving risks.
- Good drainage practices, such as using drainage tiles around foundations and ensuring proper insulation and grading, are essential for foundation integrity.
Frost-Protected Shallow Foundations (FPSF):
- FPSF designs aim to minimize frost heave potential by using insulation and non-frost susceptible fill materials, providing proper drainage, and maintaining adequate depth beyond building codes.

Understanding these concepts is crucial in preventing frost-related damage to structures and ensuring the stability and integrity of foundations in areas prone to freezing temperatures. Applying appropriate measures based on these principles can significantly reduce the risks associated with frost heave.