HomeMy WebLinkAboutKECHTER FARM FILING 2 - Filed SEPD-SURFACE EXPLORATION/PAVEMENT DESIGN REPORT - 2018-01-18TABLE OF CONTENTS
SCOPE 1
SUMMARY OF CONCLUSIONS 1
SITE LOCATION AND PROJECT DESCRIPTION 2
FIELD AND LABORATORY INVESTIGATION 2
SUBSURFACE CONDITIONS 3
PAVEMENT DESIGN 3
Traffic Projections 4
Subgrade and Groundwater Conditions 4
Pavement Thickness Calculations 5
Pavement Recommendations 5
PAVEMENT SELECTION 6
SUBGRADE AND PAVEMENT MATERIALS AND CONSTRUCTION 6
WATER-SOLUBLE SULFATES 8
MAINTENANCE 9
SURFACE DRAINAGE 9
LIMITATIONS 10
FIGURE 1 – LOCATIONS OF EXPLORATORY BORINGS
FIGURES 2 AND 3 – SUMMARY LOGS OF EXPLORATORY BORINGS
FIGURE 4 – FLEXIBLE PAVEMENT DESIGN CALCULATIONS
APPENDIX A – RESULTS OF LABORATORY TESTING
APPENDIX B – SAMPLE SITE GRADING SPECIFICATIONS
APPENDIX C – PAVEMENT CONSTRUCTION RECOMMENDATIONS
APPENDIX D – MAINTENANCE PROGRAM
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 1
CTL T PROJECT NO. FC06547.013-135
SCOPE
This report presents the results of our Subgrade Investigation and Pave-
ment Recommendations for the planned interior roadways for Phases 3 and 5 of
Kechter Farm Subdivision, Filing 2 in Fort Collins, Colorado. The purpose of our
subgrade investigation was to determine the subsurface conditions and to evalu-
ate pavement support characteristics for our pavement recommendations. The
report was conducted in general conformance with the Chapter 5 of the Larimer
County Urban Areas Street Standards (LCUASS) dated January 2, 2001 (re-
pealed and reenacted April 1, 2007) as adopted by the City of Fort Collins (City).
This report was prepared from data developed during field exploration, la-
boratory testing, engineering analysis, and experience with similar conditions.
The report includes a description of the subsurface conditions found in explorato-
ry borings, laboratory test results and pavement construction and material rec-
ommendations for the construction of Tree Row Lane and portions of Spindle-
brush Lane, Sapling Street, Fall Harvest Way, Medlar Place and Espalier Lane.
If plans change significantly, we should be contacted to review our investigation
and determine if our recommendations still apply. A brief summary of our con-
clusions is presented below, with more detailed criteria contained in the report.
SUMMARY OF CONCLUSIONS
1. Soils encountered in our borings consisted of 3½ to 6 feet of sandy
clay fill over native sandy clay to the depths explored. Bedrock and
groundwater were not encountered during this investigation.
2. The subgrade soils classified as A-7, which are considered to ex-
hibit fair to poor subgrade support.
3. Mitigation for soft subgrade and expansive soils is recommended.
We recommend treating the subgrade with fly ash.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 2
CTL T PROJECT NO. FC06547.013-135
4. Asphaltic concrete and Portland cement concrete are appropriate
surface pavements. Minimum pavement recommendations will be
provided in a supplemental report.
SITE LOCATION AND PROJECT DESCRIPTION
The project roadways are located within Kechter Farms in southeast Fort
Collins, Colorado (Figure 1). The project includes the construction of Tree Row
Lane and portions of Espalier Court, Medlar Street, Fall Harvest Way, Sapling
Street and Spindlebrush Lane. At the time of our investigation, roadways were
rough graded and buried utilities had been installed.
FIELD AND LABORATORY INVESTIGATION
Our field investigation consisted of drilling seven borings to a depth of ap-
proximately 10 feet. The approximate locations of our borings are presented on
Figure 1. The borings were drilled with 4-inch diameter solid-stem augers and a
truck-mounted drill. Our field representative logged the soils encountered and
collected samples. Drive samples were collected by driving a modified California
sampler 12 inches with blows of a 140-pound hammer falling 30 inches. This
method is similar to the standard penetration test and is typical for local practice.
Summary logs of the borings, including field penetration test results, are present-
ed on Figures 2 and 3.
Samples were returned to our laboratory and examined by the geotech-
nical engineer for this project. Laboratory testing was conducted in general ac-
cordance with AASHTO and ASTM methods to determine classifications and
subgrade support values. Laboratory testing included moisture content, dry den-
sity, swell-consolidation, water-soluble sulfates, Atterberg limits and gradation
analyses. Swell-consolidation tests were wetted at a confining pressure of 150
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 3
CTL T PROJECT NO. FC06547.013-135
pounds per square foot (psf) as required by LCUASS. Results of our laboratory
tests are presented in Appendix A and summarized in Table A-I.
Previous Investigations
CTL|Thompson, Inc. completed previous subgrade investigations and
pavement recommendations for Kechter Farm, Filing 1, Phases 1 through 4 (Pro-
ject Nos. FC06547.003-135, FC06547.005-135 and FC06547.006-135) and
Kechter Farm, Filing 2, Phases 1, 2 and 4 (Project Nos. FC06547.010-135,
FC06547.011-135, FC06547.012-135). Results from our previous investigations
were considered in preparation of this report.
SUBSURFACE CONDITIONS
Soils encountered in our borings generally consisted of 3½ to 6 feet of
sandy clay fill over sandy clay to the depths explored. No bedrock or groundwa-
ter was encountered in the borings. Swell-consolidation testing of nine samples
indicated swell potentials of 0.1 to 2.7 percent. Particle size analyses indicated
fines contents (percent passing the No. 200 sieve) of 66 to 82 percent. Further
descriptions of the subsurface conditions can be found on our boring logs and in
our laboratory test results.
PAVEMENT DESIGN
We understand the new roadways and improvements are regulated by the
City of Fort Collins which requires the use of the AASHTO and CDOT pavement
design methods for their roadways. These design methods require input param-
eters for traffic projections for a specified design life, roadway classification,
characteristics of the subgrade materials, type and strength characteristics of
pavement materials, groundwater conditions, drainage conditions, number of
construction stages, minimum pavement sections, and statistical data.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 4
CTL T PROJECT NO. FC06547.013-135
Traffic Projections
The traffic projections are based on vehicle loading, traffic volume, design
period, and growth factor. Traffic projections are expressed as an 18-kip Equiva-
lent Daily Load Application (EDLA) for a single day and as an 18-kip Equivalent
Single Axle Load (ESAL) for the design period, which is typically 20 years. An
ESAL for the roadways was provided by a representative of the City of Fort Col-
lins using a 20-year design life. Table A presents the Design ESAL used with our
calculations.
TABLE A
DESIGN 18-kip EQUIVALENT SINGLE AXLE LOADS (ESAL)
Street
Flexible ESAL, (20-
Year Design Life)
Rigid ESAL, (20-
Year Design Life)
Tree Row Lane, Espalier Court,
Medlar Street, Fall Harvest Way,
Sapling Street and Spindlebrush
Lane
36,500 36,500
Subgrade and Groundwater Conditions
The subgrade soils consist of sandy clay fill that classifies as A-7 in ac-
cordance with AASHTO classification methods. A Hveem stabilometer test of a
composite sample of the subgrade soil resulted in an R-value of less than 5. For
this soil, we believe a design R-value of 5 is appropriate.
Higher swelling soils were encountered during this investigation and have
been encountered during previous investigations. LCUASS requires swell mitiga-
tion where swell is 2 percent or greater. Based on the results of laboratory test-
ing and LCUASS, we believe that mitigation for swell will be required. Soft, yield-
ing soil is likely in some areas due to high moisture contents. Stabilization
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 5
CTL T PROJECT NO. FC06547.013-135
should improve support over soft soils. Based on these considerations and to be
consistent with adjoining roadways, we recommend the subgrade soil be stabi-
lized. Fly-ash treated subgrade is commonly used in this area to improve stabil-
ity of swelling and soft soil. Water-soluble sulfate tests indicate a single applica-
tion of fly-ash is applicable to this site.
Pavement Thickness Calculations
We used 1993 AASHTO pavement design procedures to develop our
pavement thickness calculations for both flexible and rigid pavements with input
values provided by the City, LCUASS, and our laboratory tests and observations.
For our design, we assumed the pavement would be constructed during a single
stage. Input values including initial and terminal serviceability indices, reliability
factor, layer strength coefficients, and minimum sections were provided by
LCUASS. Hveem testing of a composite sample of the subgrade soil in the la-
boratory resulted in a design R-value of 5, which we converted to a resilient
modulus of 3,020 psi based on CDOT criteria. For rigid pavement design, we
estimated a modulus of subgrade reaction (k-value) of 100 psi/in based on de-
gree of saturation and soil classification.
Pavement Recommendations
We have provided pavement design alternatives for new construction in-
cluding hot mix asphalt (HMA) on aggregate base course (ABC) and Portland
cement concrete (PCC) pavement. Pavement calculations are included in Figure
4. Pavement thickness alternatives are presented on Table B. Additional dis-
cussion regarding advantages and disadvantages of the pavement alternatives
and their expected performance is included under the PAVEMENT SELECTION
section of this report.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 6
CTL T PROJECT NO. FC06547.013-135
TABLE B
MINIMUM PAVEMENT THICKNESS RECOMMENDATIONS
Roadway
Hot Mix Asphalt (HMA) +
Aggregate Base Course
(ABC)+
Chemically Stabilized
Subgrade (CSS)
Portland Cement Con-
crete (PCC) +
Chemically Stabilized
Subgrade (CSS)
Tree Row Lane, Espalier
Court, Medlar Street, Fall
Harvest Way, Sapling
Street and Spindlebrush
Lane
ESAL = 36,500
4” HMA +
6” ABC+
12” CSS
6” PCC+
12” CSS
PAVEMENT SELECTION
Both HMA/ABC composite (flexible) and PCC (rigid) pavements are ex-
pected to perform well for the roadways. However, PCC pavement has better
performance in freeze-thaw conditions and should require less long-term mainte-
nance than HMA pavement. PCC pavement is also recommended for sections
that may experience frequent stopping and turning, heavy point loads, or chemi-
cal spills.
SUBGRADE AND PAVEMENT MATERIALS AND CONSTRUCTION
The construction materials are assumed to possess sufficient quality as
reflected by the strength factors used in our design calculations. Materials and
construction requirements of LCUASS and CDOT Standard Specifications for
Road and Bridge Construction should be followed. Subgrade preparation will only
apply to areas planned for new construction.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 7
CTL T PROJECT NO. FC06547.013-135
Based on the results of laboratory testing, LCUASS, and experience with
similar soils of the area, we recommend mitigation for swell and soft soils. We
understand for swell mitigation the City typically uses a prescribed amount of
about 12 percent fly ash stabilizing agent for 12 inches of the subgrade when a
mix design is not prepared. Lime may also be considered as an effective stabiliz-
ing agent for this project. The pavement design includes a ½-credit for chemical
treatment. If a mix design with the selected chemical stabilizing agent is per-
formed and a strength gain specified in LCUASS is achieved, credit is allowed
towards a reduction in the recommended thicknesses of pavement materials.
Minimum 7-day compressive strengths of 150 psi for fly ash treated subgrade
and 160 psi for lime treated subgrade, verified with field tests from samples ob-
tained during the field mixing operations, are required for full credit. In the event
swell is not reduced to 2 percent or less, we should be consulted to amend our
recommendations.
The method of applying the stabilizing agent to the soil will depend partly
on the level of water-soluble sulfates in the subgrade soil. A reaction of water-
soluble sulfates in the soil and available calcium in the stabilizing agent can oc-
cur creating the mineral ettringite, which can swell causing detrimental effects to
the pavement surface. If unacceptable concentrations of water-soluble sulfates
are present in the soil, the double-application method can reduce the risk of
pavement heave due to ettringite formation to an acceptable level. Concentra-
tions of water-soluble sulfates were measured in six samples at or below 0.02
percent. Our threshold limit of water-soluble sulfates in soils for single application
of fly ash or lime for stabilization is 0.5 percent. Based on our test results, we
believe single application is appropriate for the site. Recommendations for chem-
ically stabilized subgrades are presented in Appendix C. Preparation of the sub-
grade should extend from back-of walk to back-of-walk where feasible.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 8
CTL T PROJECT NO. FC06547.013-135
These criteria were developed from analysis of the field and laboratory
data, our experience and LCUASS requirements. If the materials cannot meet
these requirements, our pavement recommendations should be re-evaluated
based upon available materials. Materials planned for construction should be
submitted and the applicable laboratory tests performed to verify compliance with
the specifications.
WATER-SOLUBLE SULFATES
In addition to the interaction of water-soluble sulfates with chemical treat-
ment agents, concrete that is exposed to sulfate-rich soils can be subject to sul-
fate attack. If concrete pavements or structures will not be in contact with sulfate-
rich soils, by means of an aggregate base course layer or other materials, the
risk of sulfate attack should be low. We measured water-soluble sulfate concen-
trations in six samples from this site. Concentrations measured were 0.02 per-
cent or below.
Water-soluble sulfate concentrations less than 0.1 percent indicate Class
0 exposure to sulfate attack for concrete that is exposed to the soils, according to
the American Concrete Institute (ACI). For this level of sulfate concentration, ACI
indicates any type of cement can be used for concrete that is exposed to the
soils. In our experience, superficial damage may occur to the exposed surfaces
of highly permeable concrete, even though sulfate levels are relatively low. To
control this risk and to resist freeze-thaw deterioration, the water-to-cementitious
material ratio should not exceed 0.50 for concrete in contact with soils that are
likely to stay moist due to surface drainage or high-water tables. Concrete
should be air entrained.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 9
CTL T PROJECT NO. FC06547.013-135
Sulfate attack problems are comparatively rare in this area when quality
concrete is used. The risk is also lowered to some extent by damp-proofing the
surfaces of concrete walls in contact with the soil. ACI indicates sulfate re-
sistance for Class 1 exposure can be achieved by using Type II cement, a maxi-
mum water-to-cementitious material ratio of 0.50, and a minimum compressive
strength of 4,000 psi. We believe this approach should be used as a minimum at
this project. The more stringent measures outlined in the previous paragraph will
better control risk of sulfate attack and are more in alignment with written industry
standards.
MAINTENANCE
Routine maintenance, such as sealing and repair of cracks, is necessary
to achieve the long-term life of a pavement system. We recommend a preven-
tive maintenance program be developed and followed for all pavement systems
to assure the design life can be realized. Choosing to defer maintenance usually
results in accelerated deterioration leading to higher future maintenance costs,
and/or repair. A recommended maintenance program is outlined in Appendix D.
Excavation of completed pavement for utility construction or repair can
destroy the integrity of the pavement and result in a severe decrease in service-
ability. To restore the pavement top original serviceability, careful backfill com-
paction before repaving is necessary.
SURFACE DRAINAGE
A primary cause of premature pavement deterioration is infiltration of wa-
ter into the pavement system. This increase in moisture content usually results
in the softening of aggregate base course and subgrade soil and eventual failure
of the pavement. In addition, parts of Colorado experience many freeze-thaw cy-
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2 10
CTL T PROJECT NO. FC06547.013-135
cles each season that can result in deterioration of the pavement. We recom-
mend that subgrade, pavement, and surrounding ground surface be sloped to
cause surface water to run off rapidly and away from pavements. Backs of curbs
and gutters should be backfilled with compacted fill and sloped to prevent pond-
ing adjacent to backs of curbs and to paving. The final grading of the subgrade
should be carefully controlled so the pavement design cross-section can be
maintained. Low spots in the subgrade that can trap water should be eliminated.
Seals should be provided within the curb and pavement and in all joints to reduce
the possibility of water infiltration.
LIMITATIONS
This report has been prepared for the exclusive use of Toll Brothers Inc.
for the purpose of providing geotechnical design and construction criteria for the
proposed project. This report was prepared from data developed during our field
exploration, laboratory testing, engineering analysis, and experience with similar
conditions. The borings were spaced to obtain a reasonably accurate under-
standing of the existing pavements and subsurface conditions. The borings are
representative of conditions encountered only at the exact boring locations. Var-
iations in subsurface conditions not indicated by our borings are always possible.
The recommendations contained in this report were based upon our understand-
ing of the planned construction. If plans change or differ from the assumptions
presented herein, we should be contacted to review our recommendations.
Due to the changing nature of site characterization, standards, and prac-
tices, the information and recommendations provided in this report are only valid
for one year following the date of issue. Following that time, our office should be
contacted to provide, if necessary, any updated recommendations as appropriate
for the engineering methodologies used at that time.
LEGEND:
INDICATES APPROXIMATE LOCATION
OF EXPLORATORY BORING
INDICATES ROADWAYS INCLUDED IN
THIS INVESTIGATION
INDICATES LOT NUMBER
2 INDICATES BLOCK NUMBER
TH-1
1
HARMONY ROAD
KECHTER ROAD
INTERSTATE 25
ZIEGLER RD.
S. TIMBERLINE RD.
SITE
TRILBY RD.
1
2
3
4
5
6
7
8
9
16
15
14
13
12
11
10
9
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
1
2
3
0
5
10
15
20
25
30
35
40
0
5
10
15
20
25
30
35
40
9/12
18/12
5/12
WC=17.6
DD=112
SW=1.5
SS=<0.01
WC=16.7
DD=114
LL=44 PI=25
-200=75
WC=17.6
DD=112
SW=1.5
SS=<0.01
WC=16.7
DD=114
LL=44 PI=25
-200=75
TH-1
18/12
11/12
15/12
WC=15.7
DD=113
LL=42 PI=24
-200=71
WC=17.7
DD=111
SW=1.4
WC=17.0
DD=115
SW=0.1
SS=0.020
WC=15.7
DD=113
LL=42 PI=24
-200=71
WC=17.7
DD=111
SW=1.4
WC=17.0
0
5
10
15
20
25
30
35
40
0
5
10
15
20
25
30
35
40
11/12
8/12
10/12
WC=22.2
DD=105
SW=0.7
WC=22.2
DD=105
SW=0.7
TH-4
12/12
6/12
4/12
WC=22.2
DD=104
SW=0.4
SS=<0.01
WC=28.2
DD=90
SW=0.2
WC=22.2
DD=104
SW=0.4
SS=<0.01
WC=28.2
DD=90
SW=0.2
TH-5
17/12
8/12
12/12
WC=17.9
DD=111
SW=2.7
SS=<0.01
WC=20.5
LL=38 PI=18
-200=82
WC=17.9
DD=111
SW=2.7
SS=<0.01
Roadway(s):
Reliability 75 %
Standard Deviation 0.44
Initial Serviceability 4.5
Terminal Serviceability 2
Resilient Modulus 3,020 psi
Design ESALs 36,500
Layers
Structural
Coefficient Drainage Thickness SN
HMA 0.44 1 4 1.76
ABC 0.11 1.05 6 0.69
CSS* 0.1 1 6 0.60
SUM 3.05
*Full credit for chemical treatment toward structural design
requires a mix design be prepared and tested
FIGURE 4
Design Structural Number
2.48
Local - Residential
(All Roadways, 12" Chemical Stabilization)
Flexible Structural Design
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM PAVEMENTS
CTL|T PROJECT NO. FC06547.013-135
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
APPENDIX A
RESULTS OF LABORATORY TESTING
Sample of FILL, CLAY, SANDY (CL) DRY UNIT WEIGHT= 112 PCF
From TH - 1 AT 2 FEET MOISTURE CONTENT= 17.6 %
Sample of CLAY, SANDY (CL) DRY UNIT WEIGHT= 111 PCF
From TH - 2 AT 4 FEET MOISTURE CONTENT= 17.7 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
APPLIED PRESSURE - KSF
APPLIED PRESSURE - KSF
COMPRESSION % EXPANSION
Swell Consolidation
FIGURE A-1
COMPRESSION % EXPANSION
-4
-3
-2
-1
0
1
2
3
EXPUND ANS ION ER C ON S TA N T
PREDUE SSU RE TO W ETT IN G
-4
-3
-2
-1
0
1
2
3
E X P A N SIONC UND ER ON ST A N T
P R E SSU RE DUE TO W ET T IN G
0.1 1.0 10 100
0.1 1.0 10 100
Sample of CLAY, SANDY (CL) DRY UNIT WEIGHT= 115 PCF
From TH - 2 AT 9 FEET MOISTURE CONTENT= 17.0 %
Sample of FILL, CLAY, SANDY (CL) DRY UNIT WEIGHT= 106 PCF
From TH - 3 AT 4 FEET MOISTURE CONTENT= 21.3 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
APPLIED PRESSURE - KSF
APPLIED PRESSURE - KSF
COMPRESSION % EXPANSION
Swell Consolidation
FIGURE A-2
COMPRESSION % EXPANSION
-4
-3
-2
-1
0
1
2
3
EXPUND ANS ION ER C ON S TA N T
PREDUE SSU RE TO W ETT IN G
-4
-3
-2
-1
0
1
2
3
E X P A N SIONC UND ER ON ST A N T
P R E SSU RE DUE TO W ET T IN G
0.1 1.0 10 100
0.1 1.0 10 100
Sample of FILL, CLAY, SANDY (CL) DRY UNIT WEIGHT= 105 PCF
From TH - 4 AT 2 FEET MOISTURE CONTENT= 22.2 %
Sample of CLAY, SANDY (CL) DRY UNIT WEIGHT= 104 PCF
From TH - 5 AT 4 FEET MOISTURE CONTENT= 22.2 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
APPLIED PRESSURE - KSF
APPLIED PRESSURE - KSF
COMPRESSION % EXPANSION
Swell Consolidation
FIGURE A-3
COMPRESSION % EXPANSION
-4
-3
-2
-1
0
1
2
3
EXPUND ANS ION ER C ON S TA N T
PREDUE SSU RE TO W ETT IN G
-4
-3
-2
-1
0
1
2
3
E X P A N SIONC UND ER ON ST A N T
P R E SSU RE DUE TO W ET T IN G
0.1 1.0 10 100
0.1 1.0 10 100
Sample of CLAY, SANDY (CL) DRY UNIT WEIGHT= 90 PCF
From TH - 5 AT 9 FEET MOISTURE CONTENT= 28.2 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
APPLIED PRESSURE - KSF
COMPRESSION % EXPANSION
Swell Consolidation
Test Results
FIGURE A-4
-8
-7
-6
-5
-4
-3
-2
-1
0
1
2
3
4
5
6
7
E XP AN SI OC N U NDER O NST ANT
P RE SS U RE D UE TO W ETTIN G
0.1 1.0 10 100
Sample of FILL, CLAY, SANDY (CL) DRY UNIT WEIGHT= 111 PCF
From TH - 6 AT 2 FEET MOISTURE CONTENT= 17.9 %
Sample of FILL, CLAY, SANDY (CL) DRY UNIT WEIGHT= 107 PCF
From TH - 7 AT 2 FEET MOISTURE CONTENT= 19.6 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
APPLIED PRESSURE - KSF
APPLIED PRESSURE - KSF
COMPRESSION % EXPANSION
Swell Consolidation
FIGURE A-5
COMPRESSION % EXPANSION
-3
-2
-1
0
1
2
3
4
EXPUND ANS ION ER C ON S TA N T
PREDUE SSU RE TO W ETT IN G
-4
-3
-2
-1
0
1
2
3
E X P A N SIONC UND ER ON ST A N T
P R E SSU RE DUE TO W ET T IN G
0.1 1.0 10 100
0.1 1.0 10 100
Sample of FILL, CLAY, SANDY (CL) GRAVEL 0
% SAND 25 %
From TH - 1 AT 4 FEET SILT & CLAY 75
% LIQUID LIMIT 44 %
PLASTICITY INDEX 25 %
Sample of FILL, CLAY, SANDY (CL) GRAVEL 0
% SAND 29 %
From TH - 2 AT 2 FEET SILT & CLAY 71
% LIQUID LIMIT 42 %
PLASTICITY INDEX 24 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
Gradation
Test Results
FIGURE A-6
0.002
15 MIN.
.005
60 MIN.
.009
19 MIN.
.019
4 MIN.
.037
1 MIN.
.074
*200
.149
*100
.297
*50
0.42
*40
.590
*30
1.19
*16
2.0
*10
2.38
*8
4.76
*4
9.52
3/8"
19.1
3/4"
36.1
1½"
76.2
3"
127
5"
152
6"
200
8"
.001
45 MIN.
Sample of FILL, CLAY, SANDY (CL) GRAVEL 1
% SAND 32 %
From TH - 3 AT 2 FEET SILT & CLAY 67
% LIQUID LIMIT 44 %
PLASTICITY INDEX 25 %
Sample of CLAY, SANDY (CL) GRAVEL 1
% SAND 17 %
From TH - 6 AT 4 FEET SILT & CLAY 82
% LIQUID LIMIT 38 %
PLASTICITY INDEX 18 %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
Gradation
Test Results
FIGURE A-7
0.002
15 MIN.
.005
60 MIN.
.009
19 MIN.
.019
4 MIN.
.037
1 MIN.
.074
*200
.149
*100
.297
*50
0.42
*40
.590
*30
1.19
*16
2.0
*10
2.38
*8
4.76
*4
9.52
3/8"
19.1
3/4"
36.1
1½"
76.2
3"
127
5"
152
6"
200
8"
.001
45 MIN.
Sample of CLAY, SANDY (CL) GRAVEL 0
% SAND 34 %
From TH - 7 AT 4 FEET SILT & CLAY 66
% LIQUID LIMIT 47 %
PLASTICITY INDEX 24 %
Sample of GRAVEL % SAND %
From SILT & CLAY % LIQUID LIMIT %
PLASTICITY INDEX %
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013
Gradation
Test Results
FIGURE A-8
0.002
15 MIN.
.005
60 MIN.
.009
19 MIN.
.019
4 MIN.
.037
1 MIN.
.074
*200
.149
*100
.297
*50
0.42
*40
.590
*30
1.19
*16
2.0
*10
2.38
*8
4.76
*4
9.52
3/8"
19.1
3/4"
36.1
1½"
76.2
3"
127
5"
152
6"
200
8"
.001
45 MIN.
0
10
PASSING WATER-
MOISTURE DRY LIQUID PLASTICITY APPLIED NO. 200 SOLUBLE
DEPTH CONTENT DENSITY LIMIT INDEX SWELL* PRESSURE SIEVE SULFATES
BORING (FEET) (%) (PCF) (%) (PSF) (%) (%) DESCRIPTION
TH-1 2 17.6 112 1.5 150 <0.01 FILL, CLAY, SANDY (CL)
TH-1 4 16.7 114 44 25 75 FILL, CLAY, SANDY (CL)
TH-2 2 15.7 113 42 24 71 FILL, CLAY, SANDY (CL)
TH-2 4 17.7 111 1.4 150 CLAY, SANDY (CL)
TH-2 9 17.0 115 0.1 1,100 0.02 CLAY, SANDY (CL)
TH-3 2 18.3 110 44 25 67 FILL, CLAY, SANDY (CL)
TH-3 4 21.3 106 1.0 150 0.02 FILL, CLAY, SANDY (CL)
TH-4 2 22.2 105 0.7 150 FILL, CLAY, SANDY (CL)
TH-5 4 22.2 104 0.4 150 <0.01 CLAY, SANDY (CL)
TH-5 9 28.2 90 0.2 1,100 CLAY, SANDY (CL)
TH-6 2 17.9 111 2.7 150 <0.01 FILL, CLAY, SANDY (CL)
TH-6 4 20.5 38 18 82 CLAY, SANDY (CL)
TH-7 2 19.6 107 1.0 150 0.01 FILL, CLAY, SANDY (CL)
TH-7 4 28.5 47 24 66 CLAY, SANDY (CL)
SWELL TEST RESULTS*
TABLE A-I
SUMMARY OF LABORATORY TESTING
ATTERBERG LIMITS
Page 1 of 1
* NEGATIVE VALUE INDICATES COMPRESSION.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL|T PROJECT NO. FC06547.013
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
APPENDIX B
SAMPLE SITE GRADING SPECIFICATIONS
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135 B-1
SAMPLE SITE GRADING SPECIFICATIONS
1. DESCRIPTION
This item shall consist of the excavation, transportation, placement, and compac-
tion of materials from locations indicated on the plans, or staked by the Engineer,
as necessary to achieve site elevations.
2. GENERAL
The Soils Engineer shall be the Owner's representative. The Soils Engineer shall
approve fill materials, method of placement, moisture contents, and percent
compaction, and shall give written approval of the completed fill.
3. CLEARING JOB SITE
The Contractor shall remove all trees, brush, and rubbish before excavation or fill
placement is begun. The Contractor shall dispose of the cleared material to pro-
vide the Owner with a clean, neat appearing job site. Cleared material shall not
be placed in areas to receive fill or where the material will support structures of
any kind.
4. SCARIFYING AREA TO BE FILLED
All topsoil and vegetable matter shall be removed from the ground surface upon
which fill is to be placed. The surface shall then be plowed or scarified to a depth
of 8 inches until the surface is free from ruts, hummocks or other uneven fea-
tures, which would prevent uniform compaction by the equipment to be used.
5. COMPACTING AREA TO BE FILLED
After the foundation for the fill has been cleared and scarified, it shall be disked
or bladed until it is free from large clods, brought to the proper moisture content
and compacted to not less than 95 percent of maximum density as determined in
accordance with ASTM D 698.
6. FILL MATERIALS
Materials classifying as CL, SC, SM, SW, SP, GP, GC, and GM are acceptable.
Fill soils shall be free from organic matter, debris, or other deleterious substanc-
es, and shall not contain rocks or lumps having a diameter greater than three (3)
inches.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135 B-2
7. MOISTURE CONTENT
Fill materials shall be moisture treated. Clay soils should be moisture-treated to
between optimum and 3 percent above optimum moisture content as determined
from Standard Proctor compaction tests. Sand soils should be moistened to
within 2 percent optimum moisture content. Sufficient laboratory compaction
tests shall be made to determine the optimum moisture content for the various
soils encountered in borrow areas.
The Contractor may be required to add moisture to the excavation materials in
the borrow area if, in the opinion of the Soils Engineer, it is not possible to obtain
uniform moisture content by adding water on the fill surface. The Contractor may
be required to rake or disk the fill soils to provide uniform moisture content
through the soils.
The application of water to embankment materials shall be made with any type of
watering equipment approved by the Soils Engineer, which will give the desired
results. Water jets from the spreader shall not be directed at the embankment
with such force that fill materials are washed out.
Should too much water be added to any part of the fill, such that the material is
too wet to permit the desired compaction from being obtained, rolling, and all
work on that section of the fill shall be delayed until the material has been al-
lowed to uniformly dry to the required moisture content. The Contractor will be
permitted to rework wet material in an approved manner to hasten its drying.
8. COMPACTION OF FILL AREAS
Selected fill material shall be placed and mixed in evenly spread layers. After
each fill layer has been placed, it shall be uniformly compacted to not less than
the specified percentage of maximum density. Fill materials shall be placed such
that the thickness of loose material does not exceed 8 inches and the compacted
lift thickness does not exceed 6 inches.
Compaction, as specified above, shall be obtained by the use of sheepsfoot roll-
ers, multiple-wheel pneumatic-tired rollers, or other equipment approved by the
Engineer. Compaction shall be accomplished while the fill material is at the
specified moisture content. Compaction of each layer shall be continuous over
the entire area. Compaction equipment shall make sufficient trips to insure that
the required density is obtained.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135 B-3
9. COMPACTION OF SLOPES
Fill slopes shall be compacted by means of sheepsfoot rollers or other suitable
equipment. Compaction operations shall be continued until slopes are stable,
but not too dense for planting, and there is no appreciable amount of loose soil
on the slopes. Compaction of slopes may be done progressively in increments of
three to five feet (3' to 5') in height or after the fill is brought to its total height.
Permanent fill slopes shall not exceed 3:1 (horizontal to vertical).
10. DENSITY TESTS
Field density tests shall be made by the Soils Engineer at locations and depths of
his choosing. Where sheepsfoot rollers are used, the soil may be disturbed to a
depth of several inches. Density tests shall be taken in compacted material be-
low the disturbed surface. When density tests indicate that the density or mois-
ture content of any layer of fill or portion thereof is below that required, the partic-
ular layer or portion shall be reworked until the required density or moisture con-
tent has been achieved.
11. COMPLETED PRELIMINARY GRADES
All areas, both cut and fill, shall be finished to a level surface and shall meet the
following limits of construction:
A. Overlot cut or fill areas shall be within plus or minus 2/10 of one
foot.
B. Street grading shall be within plus or minus 1/10 of one foot.
The civil engineer, or duly authorized representative, shall check all cut and fill
areas to observe that the work is in accordance with the above limits.
12. SUPERVISION AND CONSTRUCTION STAKING
Observation by the Soils Engineer shall be continuous during the placement of fill
and compaction operations so that he can declare that the fill was placed in gen-
eral conformance with specifications. All site visits necessary to test the place-
ment of fill and observe compaction operations will be at the expense of the
Owner. All construction staking will be provided by the Civil Engineer or his duly
authorized representative. Initial and final grading staking shall be at the ex-
pense of the owner. The replacement of grade stakes through construction shall
be at the expense of the contractor.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135 B-4
13. SEASONAL LIMITS
No fill material shall be placed, spread or rolled while it is frozen, thawing, or dur-
ing unfavorable weather conditions. When work is interrupted by heavy precipi-
tation, fill operations shall not be resumed until the Soils Engineer indicates that
the moisture content and density of previously placed materials are as specified.
14. NOTICE REGARDING START OF GRADING
The contractor shall submit notification to the Soils Engineer and Owner advising
them of the start of grading operations at least three (3) days in advance of the
starting date. Notification shall also be submitted at least 3 days in advance of
any resumption dates when grading operations have been stopped for any rea-
son other than adverse weather conditions.
15. REPORTING OF FIELD DENSITY TESTS
Density tests made by the Soils Engineer, as specified under "Density Tests"
above, shall be submitted progressively to the Owner. Dry density, moisture con-
tent, of each test taken, and percentage compaction shall be reported for each
test taken.
16. DECLARATION REGARDING COMPLETED FILL
The Soils Engineer shall provide a written declaration stating that the site was
filled with acceptable materials, or was placed in general accordance with the
specifications.
APPENDIX C
PAVEMENT CONSTRUCTION RECOMMENDATIONS
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-1
SUBGRADE PREPARATION
Chemically Stabilized Subgrade (CSS)
1. Utility trenches and all subsequently placed fill should be properly
compacted and tested prior to subgrade preparation. As a mini-
mum, fill should be compacted to 95 percent of standard Proctor
maximum dry density.
2. The subgrade should be stripped of organic matter and should be
shaped to final line and grade.
3. The contractor or owner’s representative should have a mix design
performed in general accordance with ASTM D 558 using the actu-
al site soils and the approved stabilizing agent (lime, fly ash or a
combination of lime and fly ash). Scheduling should allow at least
two weeks for the mix design to be completed prior to construction.
4. High calcium quicklime should conform to the requirements of
ASTM C 977 and ASTM C 110. Dolomitic quicklime, magnesia
quicklime with magnesium oxide contents in excess of 4 percent, or
carbonated quicklime should not be used.
5. Fly ash should consist of Class C in accordance with ASTM C 593
and C 618.
6. All stabilizing agents should come from the same source as used in
the mix design. If the source is changed, a new mix design should
be performed.
7. Stabilizing agents should be spread with a mechanical spreader
from back of curb to back of curb for detached sidewalks or back of
walk to back of walk for attached sidewalks, where applicable.
8. The subgrade should be mixed to the specified depth and at the
specified concentration until a uniform blend of soil, stabilizing
agent and water is obtained and the moisture content is at least 2
percent (for fly ash) and 3 percent (for lime) above the optimum
moisture content of the design mixture (ASTM D 558).
9. If lime is used, a mellowing period of up to seven days may be re-
quired following initial mixing. Once the pH of the mixture is 12.3 or
higher and the plasticity index is less than 10, the soils shall again
be mixed and moisture conditioned to at least 3 percent over opti-
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-2
mum moisture content and compacted to at least 95 percent of the
mixture’s maximum dry density (ASTM D 558). Up to sev-
en additional days may be required for curing prior to paving. The
treated surface shall be kept moist or sealed with emulsified as-
phalt. Traffic should not be allowed on the surface during the mel-
lowing and curing periods.
10. If fly ash is used, the mixture should be moisture conditioned to at
least 2 percent over optimum moisture content and compacted to at
least 95 percent of the mixture’s maximum dry density (ASTM D
558) within 2 hours from the time of initial fly ash mixing.
11. If a lime/fly ash combination is used, the lime should be mixed first
and allowed to mellow as indicated for lime treatment in item 9.
Following the mellowing period, the fly ash should be added, mois-
ture conditioned and compacted as indicated above within 2 hours
of initial fly ash mixing.
12. Samples of loose, blended stabilizing agent/soil mixture should be
sampled by a representative of CTL Thompson, Inc. for compres-
sive strength testing (ASTM D 1663) to determine compliance (op-
tional) when full credit for the FASS layer is used in the pavement
thickness design.
13. Batch tickets should be supplied to the owner or owner’s repre-
sentative with the application area for that batch to determine com-
pliance with the recommended proportions of fly ash to soil.
14. The subgrade should be re-shaped to final line and grade.
15. The subgrade should be sealed with a pneumatic-tire roller that is
sufficiently light in weight so as to not cause hairline cracking of the
subgrade.
16. Where sulfate concentrations are over 0.5 percent, a double treat-
ment method should be performed. When a double treatment is re-
quired, the first half of the stabilizing agent should be placed, mois-
ture treated and allowed to mellow or cure for at least two weeks.
The remaining half of the stabilizing agent plus an additional 0.5
(for lime) to 2 (for fly ash) percent shall then be applied.
17. Mixing of the fly ash, lime, or lime/fly ash treated subgrade should
not occur if the temperature of the soil mixture is below 40o
F.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-3
18. We recommend a minimum of 2 days curing prior to paving. The
surface of the stabilized area should be kept moist during the cure
period by periodic, light sprinkling if needed. Strength gains will be
slower during cooler weather. Traffic should not be permitted on
the treated subgrade during the curing period. The subgrade
should be protected from freezing or drying at all times until paving.
19. The treated areas will gain greater strength if they are allowed to
cure for 1 to 3 days prior to paving. Construction traffic on the
treated subgrade prior to pavement section construction should be
limited and the subgrade should be protected from freezing or dry-
ing at all times until paving.
20. Placement, mixing and compaction of stabilized subgrade should
be observed and tested by a representative of our firm.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-4
PAVEMENT MATERIALS AND CONSTRUCTION
Aggregate Base Course (ABC)
1. A Class 5 or 6 Colorado Department of Transportation (CDOT)
specified ABC should be used.
2. Bases should have a minimum Hveem stabilometer value of 72, or
greater. ABC must be moisture stable. The change in R-value
from 300-psi to 100-psi exudation pressure should be 12 points or
less.
3. ABC bases should be placed in thin lifts not to exceed 6 inches and
moisture treated to near optimum moisture content. Bases should
be moisture treated to near optimum moisture content, and com-
pacted to at least 95 percent of standard Proctor maximum dry
density (ASTM D 698, AASHTO T 99).
4. Placement and compaction of ABC should be observed and tested
by a representative of our firm. Placement should not commence
until the underlying subgrade is properly prepared and tested.
Hot Mix Asphalt (HMA)
1. HMA should be composed of a mixture of aggregate, filler, hydrated
lime and asphalt cement. Some mixes may require polymer modi-
fied asphalt cement, or make use of up to 20 percent reclaimed as-
phalt pavement (RAP). A job mix design is recommended and pe-
riodic checks on the job site should be made to verify compliance
with specifications.
2. HMA should be relatively impermeable to moisture and should be
designed with crushed aggregates that have a minimum of 80 per-
cent of the aggregate retained on the No. 4 sieve with two mechan-
ically fractured faces.
3. Gradations that approach the maximum density line (within 5 per-
cent between the No. 4 and 50 sieves) should be avoided. A gra-
dation with a nominal maximum size of 1 or 2 inches developed on
the fine side of the maximum density line should be used.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-5
4. Total void content, voids in the mineral aggregate (VMA) and voids
filled should be considered in the selection of the optimum asphalt
cement content. The optimum asphalt content should be selected
at a total air void content of approximately 4 percent. The mixture
should have a minimum VMA of 14 percent and between 65 per-
cent and 80 percent of voids filled.
5. Asphalt cement should meet the requirements of the Superpave
Performance Graded (PG) Binders. The minimum performing as-
phalt cement should conform to the requirements of the governing
agency.
6. Hydrated lime should be added at the rate of 1 percent by dry
weight of the aggregate and should be included in the amount pass-
ing the No. 200 sieve. Hydrated lime for aggregate pretreatment
should conform to the requirements of ASTM C 207, Type N.
7. Paving should be performed on properly prepared, unfrozen sur-
faces that are free of water, snow and ice. Paving should only be
performed when both air and surface temperatures equal, or ex-
ceed, the temperatures specified in Table 401-3 of the 2006 Colo-
rado Department of Transportation Standard Specifications for
Road and Bridge Construction.
8. HMA should not be placed at a temperature lower than 245o
F for
mixes containing PG 64-22 asphalt, and 290o
F for mixes containing
polymer-modified asphalt. The breakdown compaction should be
completed before the HMA temperature drops 20o
F.
9. Wearing surface course shall be Grading S or SX for residential
roadway classifications and Grading S for collector, arterial, indus-
trial, and commercial roadway classifications.
10. The minimum/maximum lift thicknesses for Grade SX shall be 1½
inches/2½ inches. The minimum/maximum lift thicknesses for
Grade S shall be 2 inches/3½ inches. The minimum/maximum lift
thicknesses for Grade SG shall be 3 inches/5 inches.
11. Joints should be staggered. No joints should be placed within
wheel paths.
12. HMA should be compacted to between 92 and 96 percent of Maxi-
mum Theoretical Density. The surface shall be sealed with a finish
roller prior to the mix cooling to 185o
F.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-6
13. Placement and compaction of HMA should be observed and tested
by a representative of our firm. Placement should not commence
until approval of the proof rolling as discussed in the Subgrade
Preparation section of this report. Sub base, base course or initial
pavement course shall be placed within 48 hours of approval of the
proof rolling. If the Contractor fails to place the sub base, base
course or initial pavement course within 48 hours or the condition of
the subgrade changes due to weather or other conditions, proof roll-
ing and correction shall be performed again.
Portland Cement Concrete (PCC)
1. Portland cement concrete should consist of Class P of the 2005
CDOT - Standard Specifications for Road and Bridge Construction
specifications for normal placement or Class E for fast-track pro-
jects. PCC should have a minimum compressive strength of 4,200
psi at 28 days and a minimum modulus of rupture (flexural strength)
of 600 psi. Job mix designs are recommended and periodic checks
on the job site should be made to verify compliance with specifica-
tions.
2. Portland cement should be Type II “low alkali” and should conform
to ASTM C 150.
3. Portland cement concrete should not be placed when the subgrade
or air temperature is below 40°F.
4. Concrete should not be placed during warm weather if the mixed
concrete has a temperature of 90°F, or higher.
5. Mixed concrete temperature placed during cold weather should
have a temperature between 50°F and 90°F.
6. Free water should not be finished into the concrete surface. Atom-
izing nozzle pressure sprayers for applying finishing compounds
are recommended whenever the concrete surface becomes difficult
to finish.
7. Curing of the portland cement concrete should be accomplished by
the use of a curing compound. The curing compound should be
applied in accordance with manufacturer recommendations.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
C-7
8. Curing procedures should be implemented, as necessary, to pro-
tect the pavement against moisture loss, rapid temperature change,
freezing, and mechanical injury.
9. Construction joints, including longitudinal joints and transverse
joints, should be formed during construction or sawed after the
concrete has begun to set, but prior to uncontrolled cracking.
10. All joints should be properly sealed using a rod back-up and ap-
proved epoxy sealant.
11. Traffic should not be allowed on the pavement until it has properly
cured and achieved at least 80 percent of the design strength, with
saw joints already cut.
12. Placement of portland cement concrete should be observed and
tested by a representative of our firm. Placement should not com-
mence until the subgrade is properly prepared and tested.
1
APPENDIX D
MAINTENANCE PROGRAM
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
D-1
MAINTENANCE RECOMMENDATIONS FOR FLEXIBLE PAVEMENTS
A primary cause for deterioration of pavements is oxidative aging resulting
in brittle pavements. Tire loads from traffic are necessary to "work" or knead the
asphalt concrete to keep it flexible and rejuvenated. Preventive maintenance
treatments will typically preserve the original or existing pavement by providing a
protective seal or rejuvenating the asphalt binder to extend pavement life.
1. Annual Preventive Maintenance
a. Visual pavement evaluations should be performed each spring
or fall.
b. Reports documenting the progress of distress should be kept
current to provide information on effective times to apply pre-
ventive maintenance treatments.
c. Crack sealing should be performed annually as new cracks ap-
pear.
2. 3 to 5 Year Preventive Maintenance
a. The owner should budget for a preventive treatment at approxi-
mate intervals of 3 to 5 years to reduce oxidative embrittlement
problems.
b. Typical preventive maintenance treatments include chip seals,
fog seals, slurry seals and crack sealing.
3. 5 to 10 Year Corrective Maintenance
a. Corrective maintenance may be necessary, as dictated by the
pavement condition, to correct rutting, cracking and structurally
failed areas.
b. Corrective maintenance may include full depth patching, milling
and overlays.
c. In order for the pavement to provide a 20-year service life, at
least one major corrective overlay should be expected.
TOLL BROTHERS INC.
PHASES 3 AND 5 – KECHTER FARM FILING 2
CTL T PROJECT NO. FC06547.013-135
D-2
MAINTENANCE RECOMMENDATIONS FOR RIGID PAVEMENTS
High traffic volumes create pavement rutting and smooth, polished surfac-
es. Preventive maintenance treatments will typically preserve the original or ex-
isting pavement by providing a protective seal and improving skid resistance
through a new wearing course.
1. Annual Preventive Maintenance
a. Visual pavement evaluations should be performed each spring
or fall.
b. Reports documenting the progress of distress should be kept
current to provide information of effective times to apply preven-
tive maintenance.
c. Crack sealing should be performed annually as new cracks ap-
pear.
2. 4 to 8 Year Preventive Maintenance
a. The owner should budget for a preventive treatment at approxi-
mate intervals of 4 to 8 years to reduce joint deterioration.
b. Typical preventive maintenance for rigid pavements includes
patching, crack sealing and joint cleaning and sealing.
c. Where joint sealants are missing or distressed, resealing is
mandatory.
3. 15 to 20 Year Corrective Maintenance
a. Corrective maintenance for rigid pavements includes patching
and slab replacement to correct subgrade failures, edge dam-
age and material failure.
b. Asphalt concrete overlays may be required at 15 to 20 year in-
tervals to improve the structural capacity of the pavement.
20
30
40
50
60
70
80
90
100
CLAY (PLASTIC) TO SILT (NON-PLASTIC)
SANDS
FINE MEDIUM COARSE
GRAVEL
FINE COARSE COBBLES
DIAMETER OF PARTICLE IN MILLIMETERS
25 HR. 7 HR.
HYDROMETER ANALYSIS SIEVE ANALYSIS
TIME READINGS U.S. STANDARD SERIES CLEAR SQUARE OPENINGS
PERCENT PASSING
0
10
20
30
50
60
70
80
90
100
PERCENT RETAINED
40
0.002
15 MIN.
.005
60 MIN.
.009
19 MIN.
.019
4 MIN.
.037
1 MIN.
.074
*200
.149
*100
.297
*50
0.42
*40
.590
*30
1.19
*16
2.0
*10
2.38
*8
4.76
*4
9.52
3/8"
19.1
3/4"
36.1
1½"
76.2
3"
127
5"
152
6"
200
8"
.001
45 MIN.
0
10
20
30
40
50
60
70
80
90
100
CLAY (PLASTIC) TO SILT (NON-PLASTIC)
SANDS
FINE MEDIUM COARSE
GRAVEL
FINE COARSE COBBLES
DIAMETER OF PARTICLE IN MILLIMETERS
25 HR. 7 HR.
HYDROMETER ANALYSIS SIEVE ANALYSIS
TIME READINGS U.S. STANDARD SERIES CLEAR SQUARE OPENINGS
PERCENT PASSING
PERCENT RETAINED
0
10
20
30
40
50
60
70
80
90
100
0
10
20
30
40
50
60
70
80
90
100
CLAY (PLASTIC) TO SILT (NON-PLASTIC)
SANDS
FINE MEDIUM COARSE
GRAVEL
FINE COARSE COBBLES
DIAMETER OF PARTICLE IN MILLIMETERS
25 HR. 7 HR.
HYDROMETER ANALYSIS SIEVE ANALYSIS
TIME READINGS U.S. STANDARD SERIES CLEAR SQUARE OPENINGS
PERCENT PASSING
0
10
20
30
50
60
70
80
90
100
PERCENT RETAINED
40
0.002
15 MIN.
.005
60 MIN.
.009
19 MIN.
.019
4 MIN.
.037
1 MIN.
.074
*200
.149
*100
.297
*50
0.42
*40
.590
*30
1.19
*16
2.0
*10
2.38
*8
4.76
*4
9.52
3/8"
19.1
3/4"
36.1
1½"
76.2
3"
127
5"
152
6"
200
8"
.001
45 MIN.
0
10
20
30
40
50
60
70
80
90
100
CLAY (PLASTIC) TO SILT (NON-PLASTIC)
SANDS
FINE MEDIUM COARSE
GRAVEL
FINE COARSE COBBLES
DIAMETER OF PARTICLE IN MILLIMETERS
25 HR. 7 HR.
HYDROMETER ANALYSIS SIEVE ANALYSIS
TIME READINGS U.S. STANDARD SERIES CLEAR SQUARE OPENINGS
PERCENT PASSING
PERCENT RETAINED
0
10
20
30
40
50
60
70
80
90
100
0
10
20
30
40
50
60
70
80
90
100
CLAY (PLASTIC) TO SILT (NON-PLASTIC)
SANDS
FINE MEDIUM COARSE
GRAVEL
FINE COARSE COBBLES
DIAMETER OF PARTICLE IN MILLIMETERS
25 HR. 7 HR.
HYDROMETER ANALYSIS SIEVE ANALYSIS
TIME READINGS U.S. STANDARD SERIES CLEAR SQUARE OPENINGS
PERCENT PASSING
0
10
20
30
50
60
70
80
90
100
PERCENT RETAINED
40
0.002
15 MIN.
.005
60 MIN.
.009
19 MIN.
.019
4 MIN.
.037
1 MIN.
.074
*200
.149
*100
.297
*50
0.42
*40
.590
*30
1.19
*16
2.0
*10
2.38
*8
4.76
*4
9.52
3/8"
19.1
3/4"
36.1
1½"
76.2
3"
127
5"
152
6"
200
8"
.001
45 MIN.
0
10
20
30
40
50
60
70
80
90
100
CLAY (PLASTIC) TO SILT (NON-PLASTIC)
SANDS
FINE MEDIUM COARSE
GRAVEL
FINE COARSE COBBLES
DIAMETER OF PARTICLE IN MILLIMETERS
25 HR. 7 HR.
HYDROMETER ANALYSIS SIEVE ANALYSIS
TIME READINGS U.S. STANDARD SERIES CLEAR SQUARE OPENINGS
PERCENT PASSING
PERCENT RETAINED
0
10
20
30
40
50
60
70
80
90
100
WC=20.5
LL=38 PI=18
-200=82
TH-6
10/12
7/12
7/12
WC=19.6
DD=107
SW=1.0
SS=0.010
WC=28.5
LL=47 PI=24
-200=66
WC=19.6
DD=107
SW=1.0
SS=0.010
WC=28.5
LL=47 PI=24
-200=66
TH-7
DEPTH - FEET
DRIVE SAMPLE. THE SYMBOL 11/12 INDICATES 11 BLOWS OF A 140-POUND HAMMER
FALLING 30 INCHES WERE REQUIRED TO DRIVE A 2.5-INCH O.D. SAMPLER 12 INCHES.
FILL, CLAY, SANDY, MOIST, STIFF TO VERY STIFF, BROWN TO DARK BROWN
1.
NOTES:
THESE LOGS ARE SUBJECT TO THE EXPLANATIONS, LIMITATIONS AND CONCLUSIONS IN
THIS REPORT.
CLAY, SANDY, MOIST, MEDIUM-STIFF TO STIFF, BROWN, TAN
4.
LEGEND:
DEPTH - FEET
THE BORINGS WERE DRILLED ON OCTOBER 25, 2017, USING 4-INCH DIAMETER
CONTINUOUS-FLIGHT AUGERS AND A TRUCK-MOUNTED DRILL RIG.
Summary Logs of
Exploratory Borings
FIGURE 3
WC
DD
SW
-200
LL
PI
UC
SS
-
-
-
-
-
-
-
-
INDICATES MOISTURE CONTENT (%).
INDICATES DRY DENSITY (PCF).
INDICATES SWELL WHEN WETTED UNDER OVERBURDEN PRESSURE (%).
INDICATES PASSING NO. 200 SIEVE (%).
INDICATES LIQUID LIMIT.
INDICATES PLASTICITY INDEX.
INDICATES UNCONFINED COMPRESSIVE STRENGTH (PSF).
INDICATES SOLUBLE SULFATE CONTENT (%).
2.
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013-135
3. GROUNDWATER WAS NOT ENCOUNTERED IN THIS INVESTIGATION.
DD=115
SW=0.1
SS=0.020
TH-2
15/12
12/12
7/12
WC=18.3
DD=110
LL=44 PI=25
-200=67
WC=21.3
DD=106
SW=1.0
SS=0.020
WC=18.3
DD=110
LL=44 PI=25
-200=67
WC=21.3
DD=106
SW=1.0
SS=0.020
TH-3
Summary Logs of
Exploratory Borings
FIGURE 2
DEPTH - FEET
DEPTH - FEET
TOLL BROTHERS INC.
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL | T PROJECT NO. FC06547.013-135
4
5
6
7
8
1
2
3
4
5
6
7
8
9
16
15
14
13
12
11
10
9
16
15
14
13
12
11
10
9
16
15
14
13
12
11
10
9
1
2 3
4 5
Tree Row Lane 6
Spindlebrush Lane
Sapling Street
Fall Harvest Way
Medlar Place
Espalier Lane
TH-1
TH-2
TH-3 TH-4 TH-5
TH-6
TH-7
FIGURE 1
Locations of
TOLL BROTHERS INC. Exploratory Borings
PHASES 3 AND 5 - KECHTER FARM FILING 2
CTL I T PROJECT NO. FC06547.013-135
0 50' 100'
APPROXIMATE
SCALE: 1" = 100'
VICINITY MAP
(FORT COLLINS, COLORADO)
NOT TO SCALE