Laserfiche WebLink
The rainfall rate for the 1,000-year, 24-hour storm is 4.79 inches/day. The maximum leachate <br /> impingement rate estimated by the HELP model for the southern portion of the cell based on a <br /> maximum drainage length of 150-ft and a LCRS gravel permeability of 0.1 cm/sec is 0.32 inches per <br /> day. The HELP analysis shows that the designed LCRS will maintain less than one foot of head over <br /> the liner. <br /> For the northern, Class III, portion of the cell, the 1,000-yr 24-hr storm of 4.79 in/day was <br /> conservatively used rather than the 100-year, 24-hour storm precipitation of 3.25 inches/day. Based <br /> on a maximum drainage length of 200-ft and a LCRS gravel permeability of 0.1 cm/sec, the <br /> maximum leachate impingement rate estimated by the HELP model is 0.52 inches per day. The <br /> HELP analysis shows that the designed LCRS will maintain less than six-inches of head over the <br /> liner. <br /> 5.2.1 Slope LCRS <br /> The LCRS on the northern 2:1 excavated slope and on the interface liner slopes will consist of a GDN <br /> placed directly upon the HDPE geomembrane. The GDN is comprised of a sheet of geonet drainage <br /> material with a nonwoven geotextile filter fabric bonded to one side. To maintain its position on the <br /> slope, the GDN is anchored at the slope crest. The geonet component of individual panels will be <br /> joined with plastic ties, and the geotextile component will be sewn. Because the placement of the <br /> protective operations layer will not occur immediately after placement of the GDN, a protective <br /> plastic covering will be placed over the GDN to protect the geotextile component from ultraviolet <br /> (UV) deterioration. The protective plastic covering will be progressively removed and replaced with <br /> the protective operations layer in conjunction with refuse placement. <br /> The GDN transmissivity was calculated based on the anticipated leachate generation calculated by the <br /> BELP analysis. The required transmissivity is specified under the imposed loading conditions. The <br /> GDN will tie directly to the base granular drainage layer. <br /> 5.2.2 Base LCRS in Southern Portion of WMU FU-06 <br /> The base LCRS in the southern portion of WMU FU-06 will be constructed of a 12-inch-thick layer <br /> of clean granular material with a minimum hydraulic conductivity of 0.1 cm/sec draining towards <br /> leachate collection pipe trenches. The particle size of the granular drainage material has been limited <br /> to a maximum of 3/8-inch to protect against puncture of the underlying geomembrane and the <br /> overlying geotextile filter fabric, and to a maximum of 3 percent of particles finer than the No.200 <br /> sieve to maintain its permeable nature. The granular drainage material is also specified to consist of <br /> well-rounded gravel (i.e., no crushed rock will be allowed) to protect the underlying geomembrane <br /> from puncture or tears. In addition, a protective geotextile cushion will be placed between the <br /> geomembrane and granular drainage material for added geoemembrane puncture resistance. <br /> If the granular drainage material appears more angular than desired by the Engineer and QA/QC <br /> Consultant, the Contractor will be required to demonstrate the suitability of the material by utilizing <br /> an on-site test area.The test will consist of placing a 1-foot thickness of granular drainage material on <br /> a 15-foot by 30-foot piece of 60-mil HDPE geomembrane and cushion geotextile using the same <br /> equipment and procedures as the Contractor is planning to use to place the granular drainage material <br /> in WMU FU-06. The QA/QC Consultant will then inspect and, if necessary, test the 60-mil HDPE <br /> geomembrane for damage and either accept or reject the angularity of the proposed granular drainage <br /> WMU FU-06 REPORT 5-5 <br />