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0 <br />Compass Health <br />August 31, 2017 <br />JN 17399 <br />Page 7 <br />compaction of backfill near the walls should be accomplished with hand -operated <br />equipment to prevent the walls from being overloaded by the higher soil forces that occur <br />during compaction. The section entitled General Earthwork and Structural Fill contains <br />additional recommendations regarding the placement and compaction of structural fill <br />behind retaining and foundation walls. <br />The above recommendations are not intended to waterproof below -grade walls, or to <br />prevent the formation of mold, mildew or fungi in interior spaces. Over time, the <br />performance of subsurface drainage systems can degrade, subsurface groundwater flow <br />patterns can change, and utilities can break or develop leaks. Therefore, waterproofing <br />should be provided where future seepage through the walls is not acceptable. This typically <br />includes limiting cold -joints and wall penetrations, and using bentonite panels or <br />membranes on the outside of the walls. There are a variety of different waterproofing <br />materials and systems, which should be installed by an experienced contractor familiar with <br />the anticipated construction and subsurface conditions. Applying a thin coat of asphalt <br />emulsion to the outside face of a wall is not considered waterproofing, and will only help to <br />reduce moisture generated from water vapor or capillary action from seeping through the <br />concrete. As with any project, adequate ventilation of basement and crawl space areas is <br />important to prevent a buildup of water vapor that is commonly transmitted through concrete <br />walls from the surrounding soil, even when seepage is not present. This is appropriate even <br />when waterproofing is applied to the outside of foundation and retaining walls. We <br />recommend that you contact an experienced envelope consultant if detailed <br />recommendations or specifications related to waterproofing design, or minimizing the <br />potential for infestations of mold and mildew are desired. <br />The General, Slabs -On -Grade, and Drainage Considerations sections should be <br />reviewed for additional recommendations related to the control of groundwater and excess <br />water vapor for the anticipated construction. <br />SLABS -ON -GRADE <br />The building floors can be constructed as slabs -on -grade atop competent native soil or on <br />structural fill. The subgrade soil must be in a firm, non -yielding condition at the time of slab <br />construction or underslab fill placement. Any soft areas encountered should be excavated and <br />replaced with select, imported structural fill. <br />Even where the exposed soils appear dry, water vapor will tend to naturally migrate upward through <br />the soil to the new constructed space above it. This can affect moisture -sensitive flooring, cause <br />imperfections or damage to the slab, or simply allow excessive water vapor into the space above <br />the slab. All interior slabs -on -grade should be underlain by a capillary break drainage layer <br />consisting of a minimum 4-inch thickness of clean gravel or crushed rock that has a fines content <br />(percent passing the No. 200 sieve) of less than 3 percent and a sand content (percent passing the <br />No. 4 sieve) of no more than 10 percent. Pea gravel or crushed rock are typically used for this <br />layer. <br />As noted by the American Concrete Institute (ACI) in the Guides for Concrete Floor and Slab <br />Structures, proper moisture protection is desirable immediately below any on -grade slab that will be <br />covered by tile, wood, carpet, impermeable floor coverings, or any moisture -sensitive equipment or <br />products. ACI also notes that vapor retarders such as 6-mil plastic sheeting have been used in the <br />past, but are now recommending a minimum 10-mil thickness for better durability and long term <br />GEOTECH CONSULTANTS, INC. <br />