HomeMy WebLinkAboutGeotech (Ft. Pierce) #2 C,0
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Ft. Pierce 2 -
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Fort Pierce, St. Lucie County, v
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ECA Project No. T1542b
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SUBMITTED TO: PREPARED BY:
B+T Group Environmental Corporation of America
1845 Town Center Boulevard 1375 Union Hill Industrial Court, Suite A
Fleming Island, FL 32003 Alpharetta, GA 30004
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
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ENVIRONMENTAL CORPORATION OF AMERICA
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May 8, 2019
B+T Group
1845 Town Center Boulevard
Fleming Island, FL 32003
Attention: Mr. James McNicol
Subject: Geotechnical Investigation Report
Ft. Pierce 2
Off Digiorgio Road
Fort Pierce, St. Lucie County, Florida
ECA Project No. T1542b
Dear Mr. McNicol:
Environmental Corporation of America (ECA) is pleased to submit this report of our
geotechnical investigation for the proposed project. Our services were provided as authorized by
B+T Group via a purchase order approval dated April 9, 2019.
This report presents a review of the information provided to us, a description of the site and
subsurface conditions, and our recommendations. The appendices contain a Site Location Map,
Boring Location Plan and a Boring Log.
Purpose and Scope of Work
The purpose of this investigation was to obtain specific subsurface data at the site and to provide
geotechnical-related parameters for the design and construction of the foundation for a new
monopole tower.
Our scope of work included the following:
• One (1) soil test boring was drilled to a depth of 60 feet below the ground surface
(bgs). Figure 1 shows the Site Location Map. Figure 2 shows the Boring Location
Plan. Standard penetration tests (SPTs) were conducted to obtain soil samples and
SPT N-values, in accordance with ASTM D-1586.
• The depth to groundwater, if any, was measured in the boring after drilling was
completed.
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Mr.James McNicol
Page 2
• The soil samples were visually classified in accordance with ASTM D-2488 and a
boring log was prepared. The soil conditions were evaluated by a registered
professional engineer and this geotechnical report was prepared with our
recommendations.
Natural moisture contents (WCN) measurements were conducted on selected soil samples in
accordance with ASTM D-2216. We have recommended design parameters and settlements
based on the SPT N-values, an examination of the soil samples, and our experience with similar
soil conditions and structures.
Project Information
We were provided with a project site survey prepared by Stonecypher Surveying, Inc., and dated
November 14, 2018. The proposed tower would be located off Digiorgio Road, Fort Pierce, St.
Lucie County, Florida. In general, the proposed tower compound would be located within a
relatively flat terrain with a surface elevation near 17 feet Above Mean Sea Level (A.M.S.L.)
within the proposed 50-foot by 50-foot (2,500 square feet) lease area. The ground surface within
the proposed lease area is covered with low grass.
We understand that plans include constructing a 150-foot tall monopole, approximately as shown
on Figure 2 in Appendix A. We assume that the equipment building/cabinet will be a pre-
fabricated structure supported on a perimeter grade beam, spread footing or turndown slab. The
project also includes the construction of a 30-foot wide non-exclusive access and utility
easement.
Field Drilling Work
The fieldwork was conducted on May 2, 2019. Information obtained from the boring was used
to help us evaluate the subsurface conditions and to assist in formulating our recommendations.
The tower center was staked at the time of our site visit.
Local Geology and Subsurface Soil Conditions (Boring B-1)
The geology of the site is best described by the Geological Map of State of Florida, Florida
Geological Survey, and Florida Department of Environmental Protection, as being within
Anastasia Formation, with the primary soil type of Limestone. The subsurface conditions were
explored with one soil test boring, drilled approximately as shown on Figure 2.
In general, from ground surface and extending to the depth drilled of 60 feet below ground
surface (bgs), soils encountered consisted initially of Fill material manually described as fine
silty Sand, underlain by medium compact to compact dense poorly graded Sand (SP) with trace
amounts of organic matter and medium compact clayey Sand (SC) to an approximate depth of
8.5 feet, underlain by very loose to medium compact fine silty Sand (SM) and loose to very
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Mr.James McNicol
Page 3
compact dense fine to medium coarse silty Sand (SM) with trace amounts of shell fragments to
the explored depth of 60 feet.
The N-values are shown on the attached boring log and ranged from 19 to 32 blows per foot
(bpf) for the upper poorly graded sand and clayey sand layers, from 3 to 17 bpf for the middle
silty sand layers, and from 10 to over 50 bpf for the lower silty sand with shell fragment layers.
Natural moisture content (WCN) measurements were conducted on selected soil samples and
ranged from 7.0%to 24.5%.
Groundwater Level Condition
At the time drilling (ATD), a groundwater level condition was encountered at a depth of 4.4 foot
(53 inches). It should be noted that groundwater level observations made within mostly cohesive
soils during drilling could be misleading. It should be anticipated that the groundwater level will
fluctuate due to seasonal climatic changes during the year. To determine actual groundwater
level measurements, groundwater levels should be measured using observation wells installed for
prolonged periods.
Foundation Construction Recommendations
The subsurface conditions are suitable for the support of the proposed tower using a deep
foundation system.
Deep Foundation System
Based on our review of the subsurface soil conditions encountered in the boring, we offer the
following average soil parameters for the design of the new tower.
Unit Friction Soil Skin Bearing Soil
Depth Weight Angle Cohesion Kp Friction Pressure Modulus
(feet) "Y4Vet (deg) Su (psf) fs (psf) BALL(psf) Kx(pci)
( cf)
0-5.5 120 34 0 3.54 105 - 104
5.5-13.5 120/58 32 0 3.25 175 - 104
13.5-18.5 100/38 27 0 2.66 215 - 65
18.5-33.5 110/48 32 0 3.25 365 3,000 205
33.5-43.5 110/48 30 0 3.00 465 3,000 205
43.5-60 125 /63 36 0 3.85 780 7,500 520
A safety factor of 2 is used for allowable skin friction (fs). A safety factor of 5 is used for allowable soil bearing
pressure (gALL). *Below the groundwater level designer should consider the buoyant unit weight(Yb)=Ywat—Ywawr.
For KA calculation project designer, should consider KA=1/Kp.
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Mr.James McNicol
Page 4
The proposed drilled shaft should be design using a combination of skin friction and point
bearing forces. Total drilled shaft foundation settlement should be limited to 0.50-inch or
approximately 0.60% of the drilled shaft diameter (D). Final shaft diameter (D) and embedment
length (L) will depend upon final tower loading conditions. Drilled shaft lateral deflection should
not exceed a maximum value of 0.25-inch.
For these foundations ECA recommends a minimum concrete strength (f c) of 4,000 psi with a
corresponding mix design slump between 4 and 8 inches.
As an alternative and based on the existing soil conditions, project designer may consider using
multiple driven piles under a mat foundation. Driven piles may range from 12 to 16 inches in
diameter. The following table presents the relationship between the ultimate driven pile
compression load capacity, pile diameter(Diam.), and embedment length(L).
Pile Length Ultimate Driven Pile Compression Load Capacity Analysis (Kips)
(L) Pile Diameter (Diam.) (inches)
(feet) 12-inches 14-inches 16-inches
50 215 275 345
55 255 325 405
Note:A safety factor should be applied to the provided ultimate load.
Buildiniz Foundations
The proposed equipment building can be supported on a perimeter grade beam, spread footing or
turndown slab foundation. For the design of the building foundation the soils are capable of a
maximum net allowable soil bearing pressure (gALL) of 2,000 psf. A minimum depth of
foundation (Df) of 1.5 feet below final grades should be considered. Total and differential
settlements should be less than 1/2-inch and 1/4-inch, respectively.
For the design of floor concrete slabs, the designer may consider a modulus of subgrade reaction
for compacted backfill material (Ks) of 85 pounds per cubic inch (pci). Bearing pad should be
prepared and compacted prior to placing any concrete. Contractors should verify the Fill
Placement section of this report.
Soil Site Class
Based on our site evaluation and the information provided by the International Building Code
(2009), to perform a dynamic analysis the clients design engineer should consider that the soils at
the site fall under Soft Soil Profile and Site Class E.
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Mr.James McNicol
Page 5
Liquefaction Analysis for Boring B-1
As shown on the attached boring log, from approximately 13.5 feet and 18.5 feet bgs, ECA
encountered a very loose silty sand soil. A liquefaction analysis was performed for the general
profile obtained at the site using Seed and Idriss (1971) conventional procedure, an earthquake
magnitude (M) of 7.5 (Richter Scale), and an average ground surface acceleration (g) coefficient
of 0.09g, as described by the Telecommunications Structural Standard (TIA-222-G) and dated
August 2005.
For the described depth, a liquefaction safety factor of 0.98 was encountered. In general, a
minimum safety factor of 1.20 is considered safe for liquefaction analysis.
Foundation Excavations
A groundwater level was encountered near the anticipated depth of foundation. Therefore,
prospective contractor would need to consider excavation dewatering.
To avoid softening of the shallow soils exposed at the foundation bearing level, excavations
should not be left open for extended periods prior to placing reinforcing steel and concrete. If
rain or freezing weather is expected, excavations should not be completed. Leaving the
excavations at least 1-foot above final grade should protect the bearing soils from deterioration.
If the excavation must remain open overnight or if rainfall becomes imminent while the bearing
soils are exposed, we recommend that a 2 to 4-inch thick "mud-mat" of "lean" (2,000 psi)
concrete be placed on the bearing soils before the placement of reinforcing steel. If the bearing
soils are softened by surface water intrusion or exposure, the softened soils must be removed
from the foundation excavation bottom immediately prior to placement of concrete.
Fill Placement
If required, borrow materials for fill, unless otherwise specified, should consist of essentially
granular material (GM, GP, GM, GC, SW, SP or SM Unified Soil Classification System); A-2-6
or better, AASHTO Classification, as approved by the Project Geotechnical Engineer. In-situ
sandy soils could be use as backfill. These should be free from vegetation and should not
contain rocks greater than 6 inches in size.
The amount of fill required for this project depends on the planned final grades. Any fill or
backfill required to attain finished grade should be placed in layers not exceeding 8 to 10-inch
thick lifts and compacted to not less than 95% of the Modified Proctor Maximum dry density, as
determined by method (ASTM D-1557). The soil moisture content should be close to the
optimum moisture content. All required fill should meet the specified compaction criteria.
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Mr.James McNicol
Page 6
ECA does not know the capability of the surficial soil to support pavements. However, we
suggest that the upper soils be replaced by granular fill in areas of heavy traffic to improve the
subgrade support capabilities and moisture sensitivity.
Field density tests should be conducted at routine intervals as the fill is being placed to verify
that adequate compaction is achieved. Prior to placing any new fill, any soft or loose near surface
soils should be removed and the area Proof-Rolled with a heavy vehicle or a heavy compaction
vibratory roller to confirm that any unsuitable soil conditions have been discovered.
Basis for Recommendations
The subsurface conditions encountered at the boring location is shown on the Boring Log in
Appendix B. The Boring Log represents our interpretation of the subsurface conditions based on
the field logs and visual examination of field samples by an engineer. The lines designating the
interface between various strata on the Boring Log represents the approximate interface
locations. In addition, the transition between strata may be gradual. The water level shown on
the Boring Log, if any, represents the condition only at the time of our exploration.
The recommendations contained herein are based in part on project information provided to us
and only apply to the specific project and site discussed in this report. If the project information
section in this report contains incorrect information or if additional information is available,
please let us know so that we may review the validity of our recommendations.
Regardless of the thoroughness of a geotechnical investigation, there is always a possibility that
conditions between borings will be different from those at specific boring locations and that
conditions will not be as anticipated by the designers or contractors. In addition, the construction
process may itself alter soil conditions. Therefore, experienced geotechnical personnel should
observe and document the construction procedures used and the conditions encountered.
Unanticipated conditions and inadequate procedures should be reported to the design team along
with timely recommendations to solve the problems created. ECA is best qualified to provide
this service based on our familiarity with the project, the subsurface conditions, and the intent of
the recommendations and design.
We wish to remind you that we will store the soil samples for 30 days. The samples will then be
discarded unless you request otherwise.
We will be happy to discuss our recommendations with you and look forward to providing the
additional studies or services necessary to complete this project. We appreciate the opportunity
to be of service.
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Mr.James McNicol
Page 7
Please call us with any questions at (770) 667-2040.
Sincerely,
Environmental Corporation of America
-'4 1 '-,
Athulya Balakrishnan, E.I.T. Hector A. Acosta, M.S.C.E., P.E.
Project Engineer Principal Geotechnical Engineer
State of Florida Reg.No. 78902
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Appendix A Figures ����,'�OR A ACC 10
Appendix B Boring Log ��'�,�L E IV S s
No. 78902
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Atlanta,GA-Corporate Headquarters 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
APPENDIX A
Figures
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
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Source: USGS Topographic Map, Fort Pierce, FL(2018).
Fort Pierce 2
Off Digiorgio Road
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N Fort Pierce, St Lucie County, Florida =
Figure 1: Site Location Map ECA Project No.T1542b
TOE OF SLOPE
PROPOSED 150'
1s.s TOP OE DANK MONOPOLE TOWER
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POINT OF BEGINNING
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Legend: Soil Boring Location
Source: Project site survey prepared by Stonecypher Surveying Inc.,and dated 11/14/2018.
Fort Pierce 2
Off Digiorgio Road
N Fort Pierce, St Lucie County, Florida =
Figure 2: Boring Location Plan ECA Project No.T1542b
APPENDIX B
Boring Log
Atlanta,GA-Corporate Headquarters 1 1375 Union Hill Industrial Court,Alpharetta,GA 30004 1 (770)667-2040 1 www.eca-usa.com
Project: Fort Pierce 2 Environmental Corp of America Log of Boring B-1
1375 Union Hill Industrial Ct.Suite-A
Project Location: Fort Pierce, FL Alpharetta, GA 30004 Sheet 1 of 2
Project Number: T1542b (770)667-2040
Date(s)Drilled 5/2/2019 Logged By A.Balakrishnan Checked By H.Acosta
Drilling 225 inches
Drill Bit Total Depth
Method HSA Size/Type . of Borehole 60 feet bgs
Drill Rig D-57 Drilling UES Approximate 17 feet A.M.S.L.
Type Contractor Surface Elevation
Groundwater Level 4.4 feet A.T.D Sampling SPT Hammer 140 Lbs hammer
and Date Measured Method(s) Data
Borehole Backfill Cuttings Location Fort Pierce,St Lucie County,Florida
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0 1 - - Grey,fine silty Sand,trace roots,dry Fill
2 11-12-19 31 (Fill)_ — — _ _ — _ _ — Sp 7.0
Dark grey,compact dense poorly
3 15-15-17 32 ,graded Sand,damp— SP 24.5
5 4 15-18-20 38 Grey,compact dense poorly graded = SP
\Sand with trace organic matter,damp SP
5 13-10-10 20 — — — — — 12.7
Black,compact dense poorly graded
6 9-9-10 19 Sand,trace organic material,damp SC
\Same as above,medium compact,dam SM
7 6-8-9 17 — — — q 15.9
10 Grey, medium compact clayey Sand,
Lamp — —
Grey, medium compact silty Sand,trace
clay,wet
8 2-1-2 3 Dark grey/black,very loose fine to SM
15 medium coarse silty Sand,wet
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a 9 4-5-8 13 Same as above,medium compact,wet SM 16.3
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10 5-7-8 15 Brown,medium compact fine to SM
m 25 medium coarse silty Sand,wet
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11 5-7-10 17 Same as above,medium compact,wet SM 23.4
W 30
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12 4-4-3 7 Same as above,loose,wet SM 22.8
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F 13 3-5-5 10 Black,loose fine to medium compact SM
W 40 silty Sand with shell fragemnts,damp
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ENVIRONMENTAL CORPORATION OF AMERICA
Project: Fort Pierce 2 Environmental Corp of America Log of Boring B-1
1375 Union Hill Industrial Ct.Suite-A
Project Location: Fort Pierce, FL Alpharetta, GA 30004 Sheet 2 of 2
Project Number: T1542b (770)667-2040
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Black,loose fine to medium compact SM
silty Sand with shell fragemnts,damp
Grey,very compact dense fine to SM
14 4-51-49 100 medium compact silty Sand with shell 21.9
fragemnts,damp
45
Same as above,very compact dense, SM
15 38-62-50/6" 50/6" damp 19.6
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Same as above,very compact dense, SM
16 58-42-50/6" 50/6" damp
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N Same as above,very compact dense, SM
17 30-53-47 100 damp 16.7
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60 End of Boring at 60 feet bgs.
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Project: Fort Pierce 2 Environmental Corp of America Key to Log of Boring
1375 Union Hill Industrial Ct.Suite-A
Project Location: Fort Pierce, FL Alpharetta, GA 30004 Sheet 1 of 1
Project Number: T1542b (770)667-2040
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MATERIAL DESCRIPTION
1 2 L3 4 5 6 7 8 9 1 11 1 1 1
COLUMN DESCRIPTIONS
1 Depth(feet): Depth in feet below the ground surface. USCS Symbol:Graphic depiction of the subsurface material
�21 Sample Number:Sample identification number. encountered.
L3J Sample Type:Type of soil sample collected at the depth interval 1� Water Content(%):Water content of the soil sample,expressed as
shown. percentage of dry weight of sample.
® Sampling Resistance, blows/ft:Number of blows to advance driven 11 qu(tsf): Unconfined compression test
sampler one foot(or distance shown)beyond seating interval 12 qu(tsf)-Spring Tester: Unconfined Compression test value from a
using the hammer identified on the boring log. spring tester
5 SPT N-Values: SPT N-values 1 ILL(%): Liquid Limit,expressed as a water content.
6I Rec(%)/RQD(%):Core Recovery(%)and RQD IM PI (%): Plasticity Index,expressed as a water content.
171 MATERIAL DESCRIPTION:Description of material encountered.
May include consistency,moisture,color,and other descriptive
text.
® Material Type:Type of material encountered.
FIELD AND LABORATORY TEST ABBREVIATIONS
CHEM:Chemical tests to assess corrosivity PI: Plasticity Index,percent
COMP:Compaction test SA:Sieve analysis(percent passing No.200 Sieve)
CONS:One-dimensional consolidation test UC: Unconfined compressive strength test,Qu,in ksf
LL:Liquid Limit,percent WA:Wash sieve(percent passing No.200 Sieve)
MATERIAL GRAPHIC SYMBOLS
E AF11{IA Silty SAND(SM)
� �7�11i F�hII
a
w Clayey SAND(SC) �:::�:.j Poorly graded SAND(SP)
a
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TYPICAL SAMPLER GRAPHIC SYMBOLS OTHER GRAPHIC SYMBOLS
Auger sampler Grab Sample Pitcher Sample water level(at time of drilling,ATD)
2
N
a 2-inch-OD unlined split t Water level(after waiting)
s Bulk Sample HQ Rock Core
� Spoon(SPT) Minor change in material properties within a
m 3-inch-OD California w/ 2.5-inch-OD Modified Shelby Tube(Thin-walled, stratum
brass rings ' California w/brass liners fixed head) — - Inferred/gradational contact between strata
m CME Sampler NQ Rock Core —?- Queried contact between strata
W GENERAL NOTES
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1:Soil classifications are based on the Unified Soil Classification System.Descriptions and stratum lines are interpretive,and actual lithologic changes may be
�7 gradual.Field descriptions may have been modified to reflect results of lab tests.
2:Descriptions on these logs apply only at the specific boring locations and at the time the borings were advanced.They are not warranted to be representative
F of subsurface conditions at other locations or times.
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