The future of Geopier® ground improvement in the Northeast is a bright one. Pushing the boundaries of our in-house engineering and technology will take us to new heights, literally and figuratively. Say goodbye to the days of only supporting lightly-loaded, low-rise structures and say hello to the present and future of supporting taller, 10+ story structures. Here’s a round-up of our top 8 ground improvement myths.
Caving soils and/or shallow groundwater conditions preclude the use of ground improvement.
Our Geopier Impact® Rammed Aggregate Pier® and GeoConcrete® Column (GCC) systems utilize a specialty displacement mandrel that is vibrated into the ground using low-amplitude, high-frequency energy. The mandrel acts as a temporary casing, which makes these Geopier technologies a great match for sites with caving soils and/or shallow groundwater conditions. Check out our short Impact RAP and GCC video clips for a closer look at how the displacement mandrel works.
Thick layers of relatively soft soils, such as organics or clay, preclude the use of ground improvement.
In the past, the presence of soft soil layers such as organics and soft clays would generally require excavation/replacement or deep foundations such as driven piles, drilled piles, or pressure injected footings (PIFs). Today however, Geopier rigid inclusions such as grouted Impact RAP elements and GCCs help transfer loads through soft soil layers that are more than 20-feet-thick and allow for traditional shallow footing support without the need for pile caps and grade beams. Check out our blog post “Helical Drilling – A Global Leader in Geopier Rigid Inclusion Technologies” for further detail on Geopier rigid inclusions.
If relatively soft soils, such as organics or clay, are present at/near the proposed bottom-of-footing elevation, then ground improvement cannot be used.
The use of Geopier RAP elements and rigid inclusions, such as grouted Impact RAP elements or GCCs, can provide a suitable bearing subgrade for shallow footings that are close to, and sometimes within, a relatively soft soil layer such as organics or clay. Check out our case history on the Assembly Row project in Somerville, MA to see how Helical provided a ground improvement solution on a site where heavily-loaded footings were located within a thick organic layer.
Ground improvement is only suitable for lightly-loaded, low-rise structures. For more heavily-loaded, mid-rise structures, deep foundations such as driven piles, drilled piles, or pressure injected footings (PIFs) are necessary to limit settlement within acceptable tolerances.
Ground improvement is widely-used to support heavily-loaded, mid-rise structures on shallow footings and slabs-on-grade, even on sites where thick layers of unsuitable soils are present. Thus, if you are evaluating a site and you believe that deep foundations are necessary, Geopier ground improvement may offer a more cost-effective alternative. Check out our case history on the 100 College Street project in New Haven, CT to see how Helical used Geopier GCCs as a value-engineering alternative to augercast piles to support a 14-story office building and 10-story parking garage with loads that exceeded 4,000 kips and wall footing loads that surpassed 60 kips per linear foot.
Ground improvement can only be used effectively if the unsuitable soil layer thickness is less than 15- to 25- feet thick.
Advances in Geopier technology and equipment have allowed for ground improvement to be used effectively on sites where the unsuitable soils (such as fill and organics) extend well beyond 25-feet deep.
Ground improvement can be used effectively on sites with thick, natural compressible clay or inorganic silt layers, but only if the ground improvement elements fully penetrate through the clay or inorganic silt layers and into an underlying relatively dense/stiff soil layer.
It is standard practice in the Northeast to fully penetrate unsuitable man-placed fill and natural compressible organic layers (peat, organic silt) with Geopier ground improvement elements that extend into underlying natural soil layers. However, Geopier elements do not necessarily need to fully penetrate through thick, natural compressible clay or inorganic silt layers and into an underlying natural soil layer provided that total settlement in the Geopier-element-reinforced “upper zone” and unreinforced “lower zone” is acceptable. In effect, Geopier elements can be used to create an “engineered crust” in the upper zone of thick, natural compressible layers such as clay or inorganic silt.
Ground improvement always requires pre-augering at element locations and therfore always generates excess spoils.
With reference to Myth #1, our Geopier Impact RAP element and GCC systems utilize a specialty displacement mandrel that is vibrated into the ground using low-amplitude, high-frequency energy. The displacement mandrel allows for a bottom-feed construction process that typically does not require pre-augering or generate excess spoils. For sites with dense to very dense fill soils, pre-augering is sometimes required to help the mandrel penetrate though the fill. Check out our short Impact RAP and GCC video clips for a closer look at how the displacement mandrel works.
Ground improvement is only cost-effective on large projects due to relatively high mobilization costs.
Ground improvement can be a cost-effective alternative to excavate/replace, even on some smaller projects, particularly if special measures are required for excavate/replace to be feasible, such as excavation support, dewatering, and/or contaminated soil disposal. We have successfully supported relatively small projects (<5,000-7,500 SF footprint) on Geopier elements, including restaurants, banks, gas stations, and single-story retail buildings.