Michael Pacholok Purchasing and Materials ManagementDirector Division
City HaIL lath Floor. West Tower100 Queen Street WestToronto. Ontario MSH 2N2
July 10, 2017 Posted on website: (3 pages + 3 attachments)
ADDENDUM NO.2TENDER NO. 178-2017
REVISED CLOSING; 12:00 NOON (Local Time), July 18, 2017RE: CONSTRUCTION OF A NEW PREFABRICATED SERVICE YARD STAFF BUILDING AT
DON VALLEY GOLF COURSE
Please refer to the above Tender Call document in your possession and be advised of the following:
ADDITIONS & DELETIONS
The following Architectural Drawings in the Tender set are to be deleted and are to bereplaced; The Drawings were included in the CD’s previously released in Addendum 1 andform part of the tender set;
- Cover sheet & Site Plan AOl.
The following reports were included in the CD’s previously released in Addendum 1 and formpart of the tender set;
- Geotechnical Report by Golder Associates New Service Building at Don Valley Golf Courseby Golder Associates dated Nov. 30, 2016
- Geotechnical Investigation Prefabricated Building Don Valley Golf Course Service Yard byEdward Wong & Associates Inc., dated Oct. 3,2013
CLARIFICATIONS
With regard to excavation and fill below the new building refer to the Geotechnical ReportNew Service Building at Don Valley Golf Course by Golder Associates dated Nov. 30, 2016;Geotechnical Investigation Section 5. Section 1.0 of that report mentions the wood cribslocated under the existing building that will have to be investigated and removed, andreplaced with fill. As well there was 8 to 10 cu. m of lean mix concrete inserted under thesouth west end of the existing building.
N. The existing water, hydro and gas services to site, to existing remaining buildings, &equipment, fuel pumps, irrigation system, field pumps, etc. are to be maintained as useableby the Owner throughout the Construction period, even if they are to be relocated. Providenew and/or temporary service equipment, piping, conduits & cabling as required ahead ofswitchover to keep all systems operational at all the times. All switchover work shall be done
outside of owner’s regular operation time.
hi. Include for replacement of existing hydro pole with new weatherproof wooden type c/w guywires to suit service providers standards and requirements. Coordinate isolation/removal/reinstallation of power & communication cables as present with respective service providers.
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iv. In Detail 2 on Drawing E2, add branch circuit reference of A-2/4 (3#6AWG RW9O+G in it)for outdoor condensing unit AC-i.
v. On Drawing E2, in Mechanical Room, add branch circuit reference of #B-24 for HRV-i,26 for Domestic Hot Water Tank and #B-28 for Domestic Hot Water Re-circulator Pump.
Ill. QUESTIONS & ANSWERS
Qi. Are we supplying the appliances or just installing them?
Al. Kitchen appliances will be provided by Owner- it is the Contractor’s responsibility toprovide power for them & install them.
02. The structural drawings call for 4:, of underslab insulation and the architectural drawings callfor 2”. Can you please clarify the required thickness
A2. Refer to A4.Ol - 4” of rigid insulation is required under the foundation slab and gradebeams, typical.
03. There is a DSS report for the building that is to be removed and there is some abatement tobe done. The cash allowance has abatement included but the site plan drawings say toperform the required abatement as per the DSS report. Are to include the abatement in thebase price?
A3. The Cash allowance includes an amount of $15,000.00 for abatement.
04. There are a few walls that are shown in elevations to be polished ground block. The small wallin the kitchen and the corridor wall shown on the 1st page. They are WAO2 walls. The wallschedule shows WAO2 walls as drywall partitions. There is no masonry wall listed in the wallschedule on A2.OO. Can you please clarify which walls are to be polished ground block.
A4. All polished concrete block walls have been removed refer to A2.00 for Wail type legend.
05. The specs call for an anti graffiti coating. Is the coating for the exterior only or all interiorsurfaces as well?
A5. As the polished block has been removed - the anti-graffiti coating will not be used.
06. The site plan shows a water line to be brought in for a fire hydrant and reference anEaglebrooke Engineering drawing. I do not see an Eaglebrooke Engineering drawing includedin the package
A6. Refer to revised Site plan A 1.00 this item was installed in previous work and has beenremoved from the site plan drawing.
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IV. ATTACHMENTS
i. Architectural DrawingsH. GEO Report — Oct30 (33 pages)
iii. Geo Report — Nov30 (26 pages)
Should you have any questions regarding this Addendum, contact Marianne Gonzalez Angulo,Corporate Buyer, at email: [email protected].
Please attach this addendum to your Request for Tender document and be governed accordingly.Bidders must acknowledge receipt of all Addenda on the space provided on the Tender Call CoverPage as per the Process Terms and Conditions, Section 1, Item B - Addenda, of the Tender Calldocument. All other aspects of the Tender remain the same.
Yours truly,
o nne Kehoenager, Construction Services
urchasing & Materials Management
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!E EDWARD WONG
Geotechnical InvestigationProposed Prefabricated Building
Don Valley Golf Course Service YardToronto, Ontario
Prepared for:
City of TorontoSocial Development, Finance & Administration
Purchasing & Contract Mana,ement55 John Street, Metro Hall, 8 Floor
Toronto, OntarioM5V3C6
Edward Wong & Associates Inc.
34 Marcelline Crescent trgeOOG33aToronto, Ontario October 302013Canada M2K 1WTelephone: (416) 9034288Facsimile: (416) 221-0795
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Proposed Prefabncated BuildingDon Valley Golf Coune Service Yard, Toronto bge00633a
Table of Contents1. Infroduction I
2. Procedure 2
3. Subsurface Conditions 33.1 Subsoils 3
3.1.1 Topsoil 33.1.2 Pavement Sthictwe 33.1.3 Fill 33.1.4 Silty Sand 33.1.5 silt 43.1.6 Sandy Silt 4
3.2 Groundwater 4
4. Engineering Discussion and Recommendations 54.1 General S4.2 Building Consthiction 5
4.2.1 Foundation Considerations 54.2.1.1 Foundation Genera] 6
4.2.2 Excavation and Groundwater Control 74.2.3 Floor Slab Construction and Permanent Drainage 74.2.4 Site Seismic Classification 84.2.5 Backfill Considerations 9
5. Environmental Considerations 105.1 Gas Vapour Monitoring 105.2 Laboratory Testing Program 10
52.1 Comparison to the MOE’s Document entitled Soil, Groundwater and SedimentStandards for Use Under Part XV.! of the Environment Protection 11
6. General Comments I
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frge00633a
Appendix A: Logs of Borehole
Appendix B: Certificate of Chemical Analysis
Drawings
Borehole Location Plan Drawing No. 1
Guidelines for Underpinning in Soil Drawing No. 2
Drainage and Backfill Recommendations for Slab-on-Grade Drawing No. 3
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frgeOO6l3a
1. Introduction
This report presents the results of a geotechnical investigation carried out at the Don ValleyGolf Course Service Yard in Toronto, Ontario.
The project involves the proposed design and construction of a single storey prefabricatedbuilding with no basement. The footprint of the proposed prefabricated building covers anarea of about 186 m2.
The purpose of this geotechnical investigation was to determine the subsoil and groundwaterconditions at the Site and, based on this information, to provide geotechnical engineeringguidelines for the design and construction of the proposed prefabricated building.Recommendations and/or comments regarding foundation type, allowable bearing pressures,groundwater conditions, excavation and backfill, slab-on-grade construction, modulus ofsubgrade reaction, permanent drainage requirements and site seismic classifications were tobe provided.
Our Terms of Reference includes limited environmental testing on selected soil samples. Thetests were carried out to provide a preliminary assessment of environmental quality of thesoils at the Site and to determine the disposal options for excess soils to be generated fromthe Site. Results of the environmental soil testing are discussed in Section 5.2 of the report.
The comments and recommendations given in this report are based on the assumption thatthe above-described design concept will proceed into construction. if changes are madeeither in the design phase or during construction, this office must be retained to reviewthese modifications. The result of this review may be a modification of ourrecommendations or the requirement of additional field or laboratory work to checkwhether the changes are acceptable from a geotechnical viewpoint.
I
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frgeOOGS3a
2. Procedure
The fieldwork was carried out on October 22, 2013. The original plan was to advance four(4) boreholes (Boreholes I to 4) to about 5 m below grade at selected locations within thearea for the proposed building. Due to the obstruction of a boulder, Borehole I wasterminated at about 2.4 m below grade. Approximate locations of the borehole are shown onthe attached Drawing No. 1 (Borehole Location Plan).
The boreholes were advanced using a truck-mounted drill rig equipped with continuous flightsolid stem augers owned, supplied and operated by a specialist drilling contractor. Thefieldwork was supervised throughout by Edward Wong’s geotechnical personnel whomonitored the drilling and sampling operations and logged the borings.
Tests for the generation of methane gas and Total Organic Vapors were carried out inBoreholes 1 to 4, using a portable combustible gas tester (RKI Eagle multi-gas detector).
The groundwater conditions in the open boreholes were closely monitored during and uponcompletion of drilling.
All recovered soil samples were transported to Edward Wong’s laboratory for detailed visualexaminations and soil classifications. Moisture content determinations were carried out on allrecovered soil samples.
Two (2) selected soil samples were submitted to an analytical laboratory in Mississauga forchemical testing. The soil samples were tested for general and inorganic parameters. Thechemical test results are discussed in Section 5 of the report.
Borehole locations were established in the field by Edward Wong & Associates Inc. Prior tothe commencement of drilling, the borehole locations were cleared for underground utilitiesby a private locator retained by Edward Wong & Associates Inc. to minimize the potential ofcontacting them during drilling.
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto UgeOOS33a
3. Subsurface ConditionsThe subsurface stratigraphy, as revealed in the logs of borehole, consisted of a topsoil layer ora pavement structure over a discontinuous fill stratum which was in turn underlain by nativedeposits of silty sand, silt and sandy silt
3.1 Subsoil
A brief description of the soil profiles, in order of depth, follows.
3.1.1 Topsoil
Topsoil was encountered at theground surfaces in Boreholes 1,2 and 3. The topsoil layers inBoreholes I and 3 were about 125 mm thick. In Borehole 2, the topsoil layer is about450 mm thick.
3.12 Pavement Structure
Pavement structure was encountered at the ground surface in Borehole 5. The pavementstructure consisted of about 125 mm of asphaltic concrete over about 125 mm of granularbase materials. The granular base materials consisted of sand with trace silt and some gravel.The granular base materials were moist Moisture content was about 9 percent.
3.1.3 Fill
Fill, extending to depths of about 1.2 m and 1.5 m below grades, was contacted below thetopsoil in Boreholes 2 and 3. The fill materials consisted of silty sand. Rootlets, wood piecesand/or crushed limestone were noted within the fill samples recovered from Boreholes 2and 3. The fill materials were very moist. Moisture contents ranged from 13 percent to 15percent
3.1.4 Silty Sand
Silty sand was encountered below the topsoil and pavement structure in Boreholes land 4and extended to depths of about 2.4 m and 1.5 m, respectively. Silty sand was alsoencountered below the fill at a depth of about 1.2 m below grade in Borehole 2 and extendedto a depth of about 2.3 m. The silty sand was found to be compact (medium dense). Standardpenetration test “N” values ranged from II blows per 300 mm penetration to 27 blows per300 mm penetration. The silty sand was very moist Moisture contents ranged from about 9percent to 14 percent.
A boulder was encountered at about 2.4 m below grade in Borehole I.
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Proposed Prefabñcated BuildingDon Valley Golf Course Service Yard, Toronto frge00633a
3.1.5 Silt
Silt was encountered below the silty sand at depths of about 2.3 m and 1.5 m below grades inBoreholes 2 and 4 and extended to depths of about 4.95 m and 3.05 m, respectively. Silt wasalso encountered below the fill at a depth of about 1.5 m below grade in Borehole 3 andextended to a depth of about 4.5 m. The relative density of the silt ranged from loose tocompact. Standard penetration test “N” values ranged from 7 blows per 300 mm penetrationto 22 blows per 300 mm penetration. The silt was wet. Moisture contents ranged from 18percent to 27 percent
3.1.6 Sandy Silt
Loose sandy silt was encountered below the silt at a depth of about 3.05 m below grade inBorehole 4 and extended to termination depth of about 4.95 m. Standard penetration test “N”values were 6 blows per 300 mm penetration and 9 blows per 300 mm penetration. The sandysilt was wet. Moisture contents were 13 percent and 17 percent.
3.2 Groundwater
Groundwater conditions were assessed in the open boreholes during the course of thefieldwork. Borehole 1 was thy, during and upon completion of drilling. Groundwater levelsin Boreholes 2, 3 and 4 were measured at depths of about 3.05 in, 3.05 m and 2.25 in belowgrades, during and upon completion of drilling.
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frge00633a
4. Engineering Discussions and Recommendations
4.1 General
The project involves the proposed design and construction of a single storey prefabricatedbuilding with no basement.
4.2 Building Construction
4.2.1 Foundation Considerations
Based on the results of the investigation, the use of spread and strip footings to support theproposed prefabricated building is considered feasible.
Footings founded on undisturbed native soils (compact silt sand / silt) below all topsoil,existing pavement structure, fill and; sofi audi or loose soils may be designed for thefollowing recommended bearing capacities:
• Bearing Capacity at Serviceability Limit State (SLS) = 75 kPa
• Factored Bearing Capacity at Ultimate Limit State (ULS) = 125 kPa
These bearing values are generally available at 0.8 m to 1.5 m below grades in Boreholes 1 to4 drilled in the area of the proposed building. Table I below show the highest elevations atthe borehole locations where the recommended bearing values can be applied.
Table 1: Highest Elevation at Borehole Locations whereRecommended Bearing Values can be applied
Proposed Prefabricated Building
Loose silty sand and sandy silt was encountered at a depth of about 1.5 m below grade atBorehole 4 location. To minimize the risk of overstressing the underlying soils, footing in thearea of Borehole 4 should be set as high as possible.
Borehole Founding Soil Spread and Strip FootingLocation 75 kPa at SLS
125 kPaatULS
Depth (m) Elevation (m)
1 Compact Silty Sand 0.8 99.20
2 Compact Silty Sand 1.2 98.80
3 Compact Silt 1.5 98.50
4 Compact Silty Sand 0.8 99.20
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frgeOO633a
4.2.1.1 Foundation General
New footings constructed immediately adjacent to the existing building should be founded atthe same level as the existing footings to eliminate underpinning requirements.
Where footings arc stepped, a maximum level difference of 600 mm should be maintained.
Footings which are to be placed on overburden at different elevations should be located suchthat the higher footings are set below a line drawn up at 10 horizontal to 7 vertical from thenear edge of the lower footing, as indicated on the following sketch:
l.ATh FilCHER flNG
FOOTINGS AT DIFFERENT ELEVATIONS
Footings should be stepped down below any loose soils, fill and or site services and placed oncompetent and approved subgrade.
MI footings exposed to seasonal freezing conditions should be protected from frost action byat least 1.2 m of soil cover or equivalent insulation, depending on the final designrequirements.
The total and differential settlements of well designed and constructed footings placed onundisturbed native soils in accordance with the above recommendations are expected to beless than 25 mm and 15 mm, respectively.
The silty sand and silt deposits are vulnerable to inclement weather and construction traffic. Itis recommended that a mud slab be placed on the footing base excavation, immediate aftergeotechnical inspection and approval.
Prior to placement of structural concrete, all founding surfaces must be evaluated by
geotechnical personnel from Edward Wong & Associates Inc. to ensure that the founding
soils are similar to those identified in the boreholes and are capable of supporting the designsoil bearing pressure.
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frgeOO633a
4.3.2 Excavation and Groundwater Control
No major groundwater problems are anticipated during excavation at the Site. The excavationfor most parts is expected to be extended through the existing fill and terminated in upperlevel of the native deposits (silty sand and silt). Any seepage which may occur fromprecipitation or from water which may be perched in the existing fill or more peMous seamswithin glacial till can be controlled by pumping from temporary sumps. However, moredifficult conditions are anticipated during excavation in the wet silt and sandy silt deposits.
All construction works must conform to the latest edition of the Occupational Health andSafety Act (OHSA) and local regulations. With respect to the OHSA, the native soils belowthe water level are considered as Type 4 soils. The dewatered native soil, the fill, the compactsily sand! silt and loose sandy silt are considered as Type 3 soils. If an excavation containsmore than one soil type, trench and excavation slope geometry shall be governed by thehighest numbered soil
For guideline, side slopes of 1 vertical to I horizontal may be used for the temporaryexcavation anticipated, subject to geotechnical inspection during construction. Where loosesoil is encountered at shallow depth or within persistent seepage at depth, it may be necessaryto locally flatten the side slopes.
It should be noted that cobbles and boulders occur in glacial deposits. The presence ofboulders may influence the progress of excavation. Consequently, provisions should be madein the contract documents to cover any delays caused by boulder obstructions.
The exact locations and depths of the existing structures and services adjacent to theexcavation should be determined and a support system be implemented, if the structure orservices are within the zone of influence defined on the attached Drawing No. 2. It will benecessary to support existing services in the excavation, if any, where the excavation extendsbelow the existing services.
4.3.3 floor Slab Constmcton and Permanent Drainage
The floor slab may be poured as a slab-on-grade on prepared and approved subgrade.
Alt topsoil and obviously unsuitable materials should be removed from the entire floor areaThe exposed subgrade should be proof-rolled with a heavy roller and examined by qualifiedgeotechnical personnel. My soft areas detected during the proof-rolling process should bedug out. The area can then be brought up to design subgmde level with approved on-site orimported materials.
The fill materials should be clean and inorganic soil with its moisture content close to itsoptimum moisture content determined in standard Proctor maximum thy density test. The fillmaterials should be placed in lifts not more than 200 mm thick in the loose state, each liftbeing compacted to at least 98 percent standard Proctor maximum dry density (SPMDD).
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto trgeOO633a
Ml backfihling and compaction operations should be monitored by qualified geotechnicalpersonnel to approve material, evaluate placement operations and ensure the specified degreeof compaction is achieved uniformly throughout the fill
A minimum 150 mm thick layer of 19 mm clear crushed stone (moisture barrier) isrecommended directly beneath the floor slab.
A coefficient of subgrade reaction of 24 MPa! m may be used for the slab-on-gradeconstructed as recommended as above.
If a moisture sensitive floor finish is to be provided, polyethylene sheeting should be used asa vapor barrier.
Within any unheated areas and entrances to service areas, adequate insulation should beprovided below the floor slab and adjacent perimeter walls to protect them against movementdue to frost heave.
Under-floor drains are generally not required for proposed prefabricated building withoutbasement. Perimeter wall drains can be eliminated if the floor slab is at least 300 mmabove the exterior grade. Drainage and backfill recommendations for slab-on-gradeconstruction are provided in Drawing No. 3.
Around the perimeter of the proposed prefabricated building, the ground surfaces should besloped away from the structures to promote surface water mn-off and reduce groundwaterinfiltration adjacent to the foundations.
4.3.4 Site Seismic Classifications
Based on the investigation results, the Site can be classified as “Class C” (soft soil) inaccordance with Table 4.1.8.4.A, OBC 2006.
The seismic hazard design values for Toronto area are shown on Table 2 below (Table 1.2,Design Data for Selected Location in Ontario, OBC 2006; Supplementary Standard SB-I):
Table 2: Seismic Hazard Design Values for Toronto Area
Sa (0.2) Sa(0.5) Sa(l.0) Sa(2.0) PGA
L 0.26 0.13 0.065 0.015 0.l7g
PGA is the peak ground acceleration in unit of g. Sa (1) is the spectral acceleration.. T is theperiod in seconds.
Based on OBC Table 4.1 .&4B, an acceleration based site coefficient (Fa) value of I may beused.
S
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto bgeOOG33a
Based on OBC Table 4.l.8.4C, a velocity based site coefficient Wv) value of 1 may beapplied.
4.3.5 Backfill Considerations
Backfill used to satisl’ underfloor slab requirements, and service trenches, etc., should becompactible fill, i.e. clean inorganic soil with its moisture content close to its optimummoisture content determined in a Standard Proctor test.
The fill should be placed in lifts not exceeding 200 mm and compacted to minimum98 percent standard Proctor maximum thy density.
Backfill should be placed simultaneously on both sides of the foundation walls. Heavycompactors, which generate large lateral stress, should be kept at a safe distance fromsubsurface walls to avoid structural damage.
All backfllling and compaction operations should be monitored by qualified geotechnicalpersonnel to approve material, evaluate placement operations and ensure the pecified degreeof compaction is achieved uniformly throughout the fill.
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frge00633a
5. Environmental Testing
5.1 Gas Vapor Monitoring
Tests for the generation ofmethane gas and Total Organic Vapors (TOV) were carried out inall boreholes using a portable combustible gas tester, RKI Eagle multi-gas detector.
No methane was detected in any of the boreholes. Down-hole TOV readings were at non-detectable levels. No chemical odors or staining which may be indicative of contaminationwere noted in any of the samples.
5.2 Laboratory Testing Program
Two (2) selected soil samples were submitted to Maxxam Analytics in Mississauga forchemical analyses. The soil samples were analyzed for general and inorganic parameterslisted in the MOE’s Document entitled “Soil, Ground Water and Sediment Standards for Useunder Part XV. 1 of the Environmental Protection Act”, dated April 2011.
These tests were carried out to provide a preliminary assessment of the environmental qualityof the soils at the site and to determine the disposal options for the excess soil materials.Sample locations and analytical data are listed in Table 3 below. The Certificates ofChemical Analyses are provided in Appendix B.
Table 3: Sample Locations and Analytical Data
Sample I.D. Location Sample Matrix Tested For
T06045 BH 2, 552 Fill General and Inorganic0.75 — 1.2 m depth Parameters
T06046 Bil 4, 553 Native General and Inorganic1.5 — 2.0 m depth Parameters
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto frge00633a
5.2.1 Comparison to the MOE Document entitled “Soil, Ground Water and SedimentStandards for Use under Part Xvi of the Environment Protection Act’
The analytical concentrations comply with the MOE Document Table I (Background SiteConditions) Residential! Parldandl histitutionali Industrial! Community/ Commercialproperty use criteria, with the following exception.
An Electricity Conductivity (EC) concentration of 2.1 mS/cm was recorded in the soil samplerecovered from Borehole 4. The measured EC concentration exceeded the MOE DocumentTable I “Residenflall Parkland! Institutional! Industrial! Commercial! Community” propertyuse criterion of 0.57 mS/cm for EC.
The EC parameter is associated with winter road salting activities. It should be noted that theelevated EC level is not considered to be harmful for human health, but could interferencewith the growth of certain species of plants and vegetation. Therefore, near surfaceplacement of these materials are not recommended for landscaping, parkiand or agriculturalpurposes. As such, elevated level of EC do not automatically preclude disposal atdevelopment Sites accepting clean fill.
Based on the above, excess soils generated from the subject Site may be disposed of at anyland based Sites in Ontario that are being developed for Residential! InstitutionaL Industrial!Commercial! Community land uses in the area where landscaping is not intended, subject toapproval from individual receiving Site authorities.
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Proposed Prefabricated BuildingDon Valley Gait Course Service Yard, Toronto frge00633a
6. General Comments
The recommendations in this report have been based on the findings in the boreholes. Soilconditions may vary between and beyond the boreholes. Consequently, during the ifituredevelopment of the property, conditions not observed during this investigation may becomeapparent; should this occur, Edward Wong & Associates Inc. should be contacted to assessthe situation and additional testing and reporting may be required. Edward Wong &Associates Inc. has qualified personnel to provide assistance in regards to ffituregeotechnical and environmental issues related to this property.
The comments given in this report are intended only for the guidance of design engineers.Edward Wong & Associates Inc. should be retained for a general review of the final designand specifications to verit& that this report has been properly interpreted and implemented. Ifnot accorded the privilege of making this review, Edward Wong & Associates Inc. willassume no responsibility for interpretation of the recommendations in the report.
We mist that this report is satisfactory for your purposes. Should you have any questions orcomments, please do not hesitate to contact this office.
Yours truly,
Edward Wang & Associates Inc.
Edward B.H. Wong, M. Eng. P. Eng.
Distribution: Client
EW trge00633a - georpt.
(2)
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Proposed Prefabricated BuildingDon Valley Golf Course Service Yard, Toronto bgeOOG33a
Appendix ALogs of Borehole
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Edward Wong &Associates Inc. BORING NUMBER I— 34 Marcelline Crescent PAGE 1 OF I
Toronto, Ontario, 112K 2W
CUEN C4y of Toronto PROJECT KAlE Service Yard Prefabricated Buildinq
PROJECT NUMBER trqeOO6S3a PROJECT LOCATiON Don Valley Soft Course, Toronto
DATE STARTED 10122113 COMPLETED 10122)13
DRILliNG CONTRACTOR Groundwork Dri*iiq
DRIWNG METHOD Solid Stem Auqers
LOGGED BY J.J. CHECKED BY E.W.
NOTES
GROUND ELEVATION lOOm HOLE 51W 100mm
GROUJII) WATER LEVELS:
AT flUE OF DRILLING
AT END OF DMWNG._AnER DMWNG -
0
0
MATERIAL DESCRIPTION
2Z is SPINVAWE‘. 20 40 60 60
&nE Pt MU IL
b a- zs*.D 20 48 60 SO
flF*eSCON1EW(%)fl
.. a_ 20 40 60 60
an SAND- brown, very moist, compact.
-becoming grey below —1.5 m depth
-encountered boulder at —2.4 m depth
r.Bottom of hole at 2.40 m.
‘7
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t Edward Wong&Associates Inc. BORING NUMBER 2SC 34 Marcelline CrescentToronto, Ontario, M2K 2W
CliENT C1vof Toronto PROJECT MAI SeMce Yard Prefabricated Buildina
PAGE 1 OF 1
PROJECT NUMBER trqeOOG33a PROJECT LOCATION Don Valley Golf Course, Toronto
GROUND WATER LEVELS:
V AT TIME OF DRILliNG 3.05 m / EIev 96.95 mCHECKED BY LW. TAT END OF DRILliNG 3,05 m I Dcv 96.95 m
DATE STARTED 10/22)13 COMPLETED 10/22/13DRI WHO CONTRACTOR Groundwork Onling
DRIWNO METHOD Solid Stem Augers
LOGGED BY Li.
NOTES
GROUND ELEVATION lOOm HOLE SIZE 100mm
MATERIAL DESCRIPTION
AFTER DRIlLING —
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SILT- trace clay, grey, wet corupad.
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:c Edward Wong&Assoclates Inc. BORING NUMBER 3— 34 Marcelline Crescent
Toronto, Ontario, 142K 2W
ClIENT Cy of Toronto
PROJECT NUMBER troeOO633a
PROJECT NAMP SeMce Yard Prefabñted Baiq
PROJECT LOCA11ON Don Valley Golf Courw Toronto
PAGE 1 OF I
DATE STARTED 10122113 COMPLETED 10/22/13
DRILLING CONTRACTOR Grwndwoê DTflnq
DRILLING METHOD Solid Stem Aiswn
LOGGED BY J.J.
___________
GROUND E1.EVATION 100 m HOLE SIZE 100mm
GROUND WATER LEVELS:
AT ISlE OF DIUNG 3.05 m I EIev 96.95 m
TAT END OF DRILLING 3.05 m I Elev 96.95 mCHECKED BY E.W.
NOTES
__________________________ _______--
AFTER DNUJNG —
MATERIAL DESCRIPTION
moist
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Edward Wong&Assocbtes Inc. BORING NUMBER 4— 34 Marcelline CrescentPAGE 1 OF 1Toronto, Ontario, M2K 2W
CLIENT City of Toronto PROJECT NAME Service Yard Prefabricated BuildinqPROJECT NUMBER trqeOO6aJa PROJECT LOCATION Don Valley Golf Count, Toronto
DATE STARTED 10122113 COMPLETED 10/22/13 GROUND ELEVA11ON 10Cm HOLE SIZE 100mmDRILLING CONTRACTOR Groundwoth Dulling GROUND WATER LEVELS:DRILUNG METHOD Solid Stem Augers VAT TffiE OF DRILLING 2.25 m / Elev 97.75 mLOGGED BY ii. CHECKED BY EW It AT END OF DWWNG 225 m I Elev 97.75 m
_________—
NOTES
_____________________________________
AFTER DRILLING —
8! SPTNVAtUEr
20 40 60rLU
th °- MATERIAL DESCRIPTIONo
0
PPAVEMENT STRUCTURE- —125mm of asphahic concrete
.._pver —125mm oF brown sand, trace silt, some gravel, very moisj,.
‘no>0Ott0wIt
cow2-i
LEO>02
SILlY SAND- occasional silt lumps, brown, very moist,compact.
ZtUi0_
00a a
t& MC LL1S1
20 40 60 60C FiNES CONTENT (%) C
20 40 60 60I
xx
AU
$5I
sS2
7HHI
2
3
4
SILT- trace day, some sand, mollet, brown, wet. compact.
1-T
-becoming looes below -Z3 m depth ss4
-: SANDY SILT- grey, wet. loose. 4.,
:-:J1ss.
— .
.
I4.
Bottom of hole at 4.95 m.
I
26 of 66
Proposed Prefabricated BuildingDon Valley Golf Course ServIce Yard, Toronto frge00633a
Appendix BCertificate of Chemical Analysis
27 of 66
rvi m
Your Project It. TRG EGO 633ASUWt COURSE. SERVICE YARDSite Location: DON VALLEY GOLFYour C.O.C. fr 20054
AfleMlon: Edwwd WonqEdward Wong & Assodales Inc34 Marteiline CresToronto, ONM2K 2W
Report Date: 2013/10/30
CER11FICATE OF ANflYSISMA)(XAM JOB I: 8310626ReceIved: 2013110)22. 14:43
Sample Matrix: SofiIt Samples Received: 2
Dale Date MethodAnalyses Quantity Extracted Asaymd Labacwy Method ReferenceHot Water Extractable Boron 2 2013110/25 2013110129 CAM SOP-00408 R153 Na Prot 2011Free (WAD) Cyanide 2 WA 2013110)25 CAM SOP-00457 Ontario MOE CN-E30l5Conductivity2 WA 2013110/28 CAM SOP-00414 MOE 158 £3138 ‘/2Hexavalent Chromium in Soil by IC (I) 2 2013110)26 2013110/26 CAM SOP-00436 EPA SW846-306011199Add ExIt-. Metals (aqua regla) by ICPMS 2 2013110/25 201311(1/28 CAM SOP-00447 EPA 6020Moisture2 WA 2013110/25 CAM SOP-00445 Rtarter,1 993pH CaCI2 EXTRACT 2 2013110126 2013110/28 CAM SOP-00413 SM 450014+ BSodium Adsorption Ratio (SAR) 2 2013110/22 2013110129 CAM SOP-00102 EPA 6010
• RPDs celailated using raw data. The rounding of final results may result In the apparent difference.• Results relate only to the items tested.
(1) Soils am reported on a dry weight basis unless otherwise spedfled.
Encryption Key— Balbfli
30 Cd 2013 I 15&29 -OttoPlease dked all quesii,nAJ this Certificate of Analysis to yXJC Project Manager.
Gina Baybayan, Project ManagerEmail: GBaybayan©maxxam.caPhone# (905) 817-5766
Maxxam has procedures in place to guard against improper use &the electronic signature and have the required signatcdeC, as per section510.2 of ISO/lEG 17025:2005(E). signing the reports. For Service Group specific ‘alidafion please refer to the Validation Signature Page.
Total cever pages: 1
Page 1 of 8
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Proposed Prefabñcatad BuildingDon Valley Golf Course Service Yard, Toronto frgeOO6S3a
DrawingsBorehole Location Plan
Guideline for Underpinning in SoilDrainage and Backfill Recommendations
for Slab-on-Grade Construction
36 of 66
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Project: frgeOO633a Drawing No. 2
2N’
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1 TIGHTLY BRACED/TIED1 4-EXCAVA11ONWALL
A1 \ B
‘S /N. \ BASE OF EXCAVATIONC/‘\:N / 4
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Zone A Foundations located within this zone normally requireunderpinning. Horizontal and vertical pressures on theexcavation wall of non underpinned foundations mustbe considered
Zone B Foundations located within this zone normally do notrequire underpinning. Horizontal and vertical pressureson the excavation wall of non underpinned foundationsmust be considered
Zone C Underpinning to structures is normally founded in thiszone. l_ateml pressure from underpinning is not normaflyconsidered
(Figure 27.16 from Canadian Foundation Engineering Manual, 3” Edition)
Guidelines for Underpinning in Soil
38 of 66
Project: TrgeOO633a Drawing No.3
Exterior Grade (10)Bhnding (6)
Moisture Barrier U)
Subgrade
Interior Backfill (5,6)
1. Drainage tile to consist of 100 mm (4”) diameter weeping tile or equivalent perforatedpipe leading to a positive sump or outlet. Invert to be a minimum of 150 mm (6”) belowunderside of floor slab.
2. Pea gravel - 150 mm (6”) top and side of drain. If drain is not on footing, place 100 mm(4 inches) of pea gravel below drain. 20 mm (3/4”) clear stone is an alternative providedit is surrounded by an approved porous plastic membrane (Terrafix 270R or equivalent).
3. G.S.A. fine concrete aggregate to act as filter materiaL Minimum 300 mm (12”) top andside of tile drain. This may be replaced by an approved porous plastic membrane asindicated in (2).
4. Impermeable backfill seal - compacted clay, dayey sift or equivalent. If original soil isfree-draining, seal may be omitted.
5. The interior fill may be any clean non-organic soil which can be compacted to thespecified density in this confined space.
6. Do not use heavy compaction equipment within 450 mm (18”) of the wall, Do not fill orcompact within 1.8 m (6’) of the wall unless fill is placed on both sides simultaneously.
7. Moisture barrier to be at least 200 mm (8”) of compacted dear 20 mm (314”) stone orequivalent free draining material.
8. If the 20 mm (3/4”) stone requires surface blinding, use 6 mm (1/4”) stone chips.9. Slab on grade should not be structurally connected to the wall or footing.
10. Exterior grade to slope away from building.
DRAINAGE AND BACKFILL RECOMMENDATIONSFOR SLAB ON GRADE CONSTRUCTiON
(not to scale)
Note:This system is not normally required if the floor slab is at least 300 m (1’) above the exterior grade.
Impermeable Seal (4,6)Slab on grade (9)
c.SA fine
Pea Gravel (2)
Drainage Tile (1)
Notes
Exterior Footing
39 of 66
40 of 66
GolderwAssociates
November 30, 2016 Project No. 1544818 (13000)
Mr Mark GoulartSenior Project CoordinatorCity of TorontoParks, Forestry & RecreationParks Development & Capital ProjectsEtobicoke Civic Centre399 The West MallMain Floor, North BlockToronto, ON M9C 2Y2
GEOTECHNICAL INVESTIGATIONNEW SERVICE BUILDING AT DON VALLEY GOLF COURSE, 4070 YONGE STREET, TORONTO, ONTARIO
Dear Mr Goulart;
Colder Associates Ltd. (Golder) has been retained by the City of Toronto (“the City”) to provide geotechnical
engineering services in support of the proposed construction of a new prefabricated service building at the Don
Valley Golf Course. The site is located northwest of the intersection of Yonge Street and Wilson Avenue in North
York, Toronto, Ontario. The terms of reference and scope of work for this project are outlined in Golder’s proposal
dated August 30, 2016. Authorization to proceed with this investigation was received by email from Mr. Mark
Goulart, Senior Project Coordinator with the City, on September 7, 2016 (CRO#901 9005) and this project is being
executed under the blanket contract number 47019624 with the City.
The purpose of the investigation was to assess the general subsurface soil and groundwater conditions at the site
by means of a limited number of boreholes and laboratory tests. Based on an interpretation of the factual
information available for this site, a general description of the subsurface conditions at the locations of the
proposed building is presented. The interpreted subsurface conditions and available project details were used to
prepare engineering recommendations for the geotechnical design aspects of the project, including construction
considerations which could influence design decisions.
The factual data, interpretations and recommendations contained in this report pertain to a specific project as
described in the report and are not applicable to any other project or site location. If the project is modified in
concept, location or elevation, or if the project is not initiated within eighteen months of the date of the report,
Colder should be given an opportunity to confirm that the recommendations are still valid.
This document should be read in conjunction with the “Important Information and Limitations of This Report”,
following the text of this report. The reader’s attention is specifically drawn to this information, as it is essential for
the proper use and interpretation of this document.
Our professional services for this assignment address only the geotechnical (physical) aspects of the subsurface
conditions at this site. Ceo-environmental (chemical) and hydrogeological aspects of the project, including
consequences of possible surface and/or subsurface contamination resulting from previous activities or uses of
the site and/or resulting from the introduction onto the site of materials from off-site sources, are not addressed
herein.
Solder Associates Ltd.140 Renfrew Oriee, Stale 200 Marltham, Ontano, Canada L3R 603Tel +1 )905) 476 5691 Fax. + 1 )905) 475 5267 vrttw.goider corn
Colder Associates: Operations in Africa, Asia, Auslralaa[a, EtIrolte, North America and South America
Colder. Colder Associates and the GA globe design are trademarics of Colder Assooates Corporation.
41 of 66
Mr. Mark Goulal 1544818 (13000)
Senior Project Coordinator — November 30, 2016
1.0 SITE AND PROJECT DESCRIPTION
The site is located at 78 Wilson Avenue, northwest of the intersection of Wilson Avenue and Yonge Street inToronto. Ontario as shown on Figure 1 (attached). The site is occupied by the existing single storey slab-on-gradeservice building laid out in an east to west direction, Adjacent to the east end of the existing service building is arecently built single storey slab on grade storage building, as shown on Figure 2 (attached). An access road leadingto Yonge Street is located on the north side of the existing service building. The area immediately south of theexisting service building is an asphalt paved area used for parking and access and the remainder of the site isoccupied by a garage and fuel storage tanks located on the south side of the site. The site is located at the top ofthe east bank of Don River West Branch.
At the time of writing this report only preliminary information related to the proposed new construction wasavailable. Based on our conversation with Bill Lobb Architect, the west portion of the one storey brick building hasnotable signs of distress. A previous geotechnical investigation (not provided) suggests that the west portion ofthe building is supported on timber cribbing. It is further understood that the existing building will be demolishedand a new pre-fabricated one storey slab-on-grade building (tilt-up construction) will be constructed.
We understand that the foundations of the existing adjacent storage building consist of shallow conventionalspread/strip footings.
2.0 REGIONAL GEOLOGY
The surf icial geology aspects of the general site area are presented in the following publication:
Chapman, L. J., and Putnam, D.F., 2007, “The Physiography of Southern Ontado Ontario GeologicalSurvey.
Physiographic mapping in the area according to the above noted reference indicates that the site lies within thephysiographic region known as the South Slope. The surficial geology mapping indicates that the site is within anarea of modern alluvial deposits consisting of clay, silt, sand, gravel and may contain organic remains. The resultsof this investigation are generally consistent with the physiographic mapping.
3.0 FIELD INVESTIGATION
The field work for this subsurface investigation was carried out on October 18, 2016, at which time five horeholes(BH16-1 to BH16-5) were advanced at the locations shown on the Borehole Location Plan, Figure 2. The boreholeswere advanced to depths of about 6.6 m to 8.1 m below the existing ground surface.
The boreholes were drilled using a standard drill rig outfitted with 110 mm diameter solid stems augers suppliedand operated by Geotech Support Services Inc. of Markham, Ontario. Standard Penetration Testing (SPT) andsampling were carried out at regular intervals of depth in the boreholes using conventional 38 mm internal diametersplit spoon sampling equipment driven by an automatic hammer in general accordance with the SPT proceduresoutlined in ASTM Dl 586. The results of the in situ field tests (i.e.. SPT “N”-values) as presented on the Record ofBorehole sheets and in subsequent sections of this report are uncorrected.
The groundwater conditions were noted in the open boreholes during drilling. Two 19mm diameter PVCpiezometers were installed in BH16-1 and BH1 6-3 to allow further groundwater level monitoring. A sand filter packsurrounds the screen in the piezometer and above the screen the borehole and annulus surrounding the PVC pipewere backfilled to the ground surface with bentonite pellets. The remaining boreholes were backfilled uponcompletion in accordance with Ontario Regulation 903 (as amended).
Prior to drilling, the borehole locations were marked in the field by Golder personnel. The field work for thisinvestigation was monitored by a member of our geotechnical staff, who arranged for the clearance of underground
‘GoIder218 .‘Associates
42 of 66
Mr. Mark Goulart 1544818 (13000)
Senior Project Coordinalor November 30, 2016
services, observed the drilling, sampling and in situ testing operations, and logged the boreholes. The soil samples
obtained during this investigation were identified in the field! placed in appropriate containers! labelled and
transported to our Markham laboratory for further detailed visual examination by the project engineer, water
content and classification testing.
The ground surface elevations at the borehole locations were derived from a topographic survey AutoCAD drawing
for the site provided by Bill Lobb Architect by email on November 3,2016! and the elevations should be considered
to be approximate. It is understood thatthe elevations shown on the topographic survey drawing are referenced
to Geodetic datum.
4.0 SUBSURFACE CONDITIONS
The subsurface soil and groundwater conditions encountered in the boreholes are shown in detail on the Record
of Borehole sheets attached. Grain size distribution curves for selected soil samples are attached. Method of Soil
Classification and Symbols and Terms Used on Records of Boreholes and Test Pits are provided to assist in the
interpretation of the borehole logs.
It should be noted that the stratigraphic boundaries shown on the Record of Borehole sheets have been inferred
from non-continuous sampling, observations of drilling progress and the results of Standard Penetration Testing.
They generally represent a transition from one soil type to another and should not be inferred to represent an exact
plane of geological change. Further! conditions will vary between and beyond the boreholes. The following is a
summarized general description of the subsurface conditions encountered in the boreholes advanced during this
site investigation.
4.1 Summary of Subsoil Conditions
The subsurface conditions consist of asphalt or topsoil overlying loose to compact non-cohesive fill. The fill deposit
is underlain by deposits of loose to dense clayey silt! sandy silt and silt encountered at depths ranging from about
2.4 m to 4.0 m below the existing ground surface. The following table provides additional details of the subsurface
conditions encountered:
Table 1: Summary of Subsurface Conditions
Depth (m) Natural
Soil Type SPT “N”-valuesConsistency Water
IState ContentFrom To (%)
Sandy Silt, SiltySand! Sand and 4 to 24 blows per Very loose to
3 to 43Fill Gravel! Sand! 0.2 to 0.3 2.4 to 4.0 0.3 m of penetration1 compactGravelly Sand,
Clayey_Silt
Native Sandy Silt! Silt! 6 to 31 blows per Loose to 16 to 282.4to4.0 6.62to8.12Soil Clayey Silt 0.3 en of penetration compact
Notes:
I One SPT !!Nvalue measured in the fill in Borehole 1 was 51 blows per 0.3 m of penetration but was likely
caused by a brick obstruction.
2. Borehole termination depth.
4.2 Groundwater Levels
Groundwater level measurements in the piezometers taken on November 4, 2016! indicate groundwater levels at
the depths of 3.5 m and 3.8 m in BH16-1 and BH16-3, respectively. It should be noted that the groundwater
*Gthfr3/8 Associates43 of 66
Mr Mark Goularl 1544818(13000)Senior Project Coordinator November 30. 2016
measurements reflect the groundwater conditions encountered in the boreholes at the time of the field work inOctober and November. 2016. Groundwater levels at the site are anticipated to fluctuate with seasonal variationsin precipitation and snowmelt.
5.0 GEOTECHNICAL RECOMMENDATIONS
5.1 Foundation Design
Based the subsurface conditions encountered and discussions with the architect, the following foundation optionsmay be considered:
Conventional shallow strip/spread footings founded on engineered fill; or
Use of helical piles.
5.1.1 Footings in Engineered Fill
The existing fill materials are not considered suitable to support the foundations of the proposed new building.Consideration may be given to supporting conventional spread or strip footings bearing on engineered fill at aminimum depth of 1.2 m below the existing ground surface. The existing fill materials extending to depths of 2.4 mto 4.0 m will have to be removed and replaced with engineered fill.
If removal of the existing fill and replacing with engineered fill is considered feasible or practical, Golder can providebearing capacity recommendations for the conventional shallow strip/spread footing founded in engineered fill.
5.1.2 Helical Piles
If removal of the existing fill materials is not considered feasible, consideration may be given to supporting thefoundation on helical piles founded in the native silt to sandy silt deposits underlying the fill.
Typically, helical piles are considered a proprietary foundation system due to variability in the use of pile materialsand installation methods. Therefore, the detailed design and verification of the installed capacity of helical piles isthe responsibility of the proprietary foundation system designer/installer. The helical piers can generally beinstalled using portable equipment.
Helical piers would be augered into the ground, advanced through the fill and founded in the native deposits belowthe frost depth. The installation should be monitored by the geotechnical engineer to confirm that the piles arefounded in the native deposits and installed according to the project specifications. The pile contractor should bemade aware that the existing fill contains brick fragments and potentially other obstructions which could affect theinstallation of the piles.
5.2 Floor SlabDue to the variability of the existing fill materials and based on information provided which indicates that the existingslab is settling, we recommend that the existing fill be removed from the building footprint under the floor slab,which would require excavation up to about 4 m below ground surface on the west side and 2.6 mon the east sideof the existing building. Excavation to this depth would also require active dewatering to ensure that thegroundwater table is lowered to about 1 ‘n below the base of the excavation prior to placement of engineered fill.The existing fill material is not considered suitable for reuse as engineered fill based on the borehole information.However, during excavation of the existing fill, a further evaluation of the existing fill can be carried out andapproved excavated fill material which is free of organics and other deleterious materials may be reused as backfillfor supporting the floor slab, subject to geotechnical inspection during construction. The geotechnical engineermust approve the exposed base of the excavation prior to backfilling.
Gohier4/8 ‘Associates
44 of 66
Mr. Mark Goulart 1544818 (13000)
Senior Project Coordinator November 30, 2016
Alternatively, if removal of all of the existing fill within the building footprint is not feasible or practical the new slab
can be designed as a structural slab. To reduce the likelihood of cracking of the structural slab, the upper 1 m of
the existing fill can be removed and replaced with engineered fill. After subexcavation to a depth of about 1 m, the
existing exposed fill area should then be proofrolled with a heavy vibratory compactor and inspected by Golder, to
confirm that the exposed fills are generally competent! and have been adequately cleaned of ponded water and
disturbed, loosened, softened materials or poorly performing zones. Remedial work during construction
(i.e. further sub-excavation) should be carried out as directed by Golder to remove any large or unsuitable debris
that could impact proofrolling/compaction operations. In general! the fill can be left in place below a depth of 1 m,
unless pockets/areas are worse than what was encountered in our boreholes. Given the length of time the fill has
been in place and the variability of its composition, additional sub-excavation below 1 m depth in some areas
should be expected and prepared for in the contract.
The base of the excavation below the proposed slab, Granular ‘A’ base and engineered fill should extend a
minimum distance out from the edge of the building footprint equal to the depth of the excavated fill, or 1.2 m,
whichever is greater.
Imported non-frost susceptible granular fill which conforms to OPSS.PROV (Aggregates) 1010 Select Subgrade
Material (SSM) can be used as engineered fill. The final lift directly beneath the floor slabs should consist of a
minimum of 150 mm of OPSS.PROV (Aggregates) 1010 Granular ‘A’ material, uniformly compacted to at least
100 percent of standard Proctor maximum dry density. This should provide a modulus of subgrade reaction of
approximately 20 MPa/m. Imported materials used for engineered fill must be approved by Golder at the source(s),
prior to hauling to the site. The water content of the materials for use as engineered fill must be within the range
of no less than 2% and no greater than 1% of the optimum moisture content for compaction. In any event, the
approved materials for engineered fill should be placed in maximum 200 mm loose lifts and uniformly compacted
to at least 100% of the SPMDD throughout. Removal of the existing fill and placement of compacted engineered
fill must be carried out under full time monitoring by the geotechnical engineer. The final surface of the engineered
fill and granqlar/bedding layers should be protected as necessary from construction activities and freezing weather.
5.3 Excavations and Temporary Support
Excavation will be required during the removal of the existing fill. Excavation to the depths of 1 m to 4 m below
the existing ground surface will encounter loose to compact non-cohesive fill. It is anticipated that excavation can
be carried out using conventional hydraulic excavating equipment with the excavations likely consisting of
conventional temporary open cuts.
Groundwater control measures in the excavation which do not extend below the groundwater level can likely be
handled by conventional pumping from sumps located within the excavations. However, should seasonal
conditions result in higher water levels, groundwater seepage into the excavation should be expected. Excavation
below the groundwater level will require active dewatering to ensure that the groundwater table is lowered to about
1 m below the base of the excavation. Refe to Section 4.2 and the Record of Borehole sheets attached for
groundwater level measurements. An accurate prediction of the groundwater pumping volumes cannot be made
at this time, as the flow rate would be dependent on construction methods adopted by the contractor. An
application under the Environmental Activity and Sector Registry (EASR) of the Ontario Ministry of the Environment
and Climate Change should be submitted in the event that the pumping volumes exceed 50,000 Uday. Under the
EASR, a Permit to Take Water is not required for water taking for construction site dewatering for volumes less
than 400,000 Uday.
The existing generally loose to compact fill to be excavated as described above may generally be classified as
Type 3 soils according to the Occupational Health and Safety Regulations for Construction Projects and all
Golder5/8 rLd’Assaciates
45 of 66
Mr Mark Goulart 1544818 (13000)
Senior Project Coordinator November 30. 2016
excavations through these soils should be sloped no steeper than 1 horizontal to 1 vertical above the groundwaterlevel and 3 horizontal to 1 vertical below the groundwater level.
However, depending upon the construction procedures adopted by the contractor, actual groundwater seepageconditions, the success of the contractor’s groundwater control methods (if required) and weather conditions at thetime of construction, some flattening and/or blanketing of the slopes may be required. Care should be taken todirect surface runoff away from the open excavations and all excavations should be carried out in accordance withthe Occupational Health and Safety Act and Regulations for Construction Projects.
Where the side slopes of excavations are required to be steepened to limit the extent of the excavation, some formof excavation support will be required (e.g.. soldier pile and lagging or steel sheet piles). The shoring method(s)selected to support the excavation must take into account the soil stratigraphy, the groundwater conditions, themethods adopted to control the groundwater, effects of weather and the ground movements associated with theshoring system and their impact on adjacent structures and utilities. The shoring systems may require bracingand/or support such as struts. The excavation support system should be designed to resist lateral earth pressuresof the soils, hydrostatic pressures and any surcharges while limiting ground movements to tolerable levels. Ifshoring is implemented at the site, the requirements of OPSS.PROV 539 should be followed and the systemshould be designed by a Professional Engineer including assessment of the potential for basal heave. It is acommon practice for a specialist contractor to design and install the excavation support system.
Temporary excavation support may be required to protect the adjacent utilities or foundations from disturbanceduring construction, depending on the depth and location of the utilities/foundations relative to the excavation. The
existing structures or utilities can be protected by bracing the sides of the excavation or by underpinning theexisting structure.
5.4 Seismic Consideration
The Ontario Building Code contains seismic analysis and design methodology. The seismic site classificationmethodology outlined in the OBC is based on the subsurface conditions within the upper 30 m below grade. Twomethods of defining the site class are presented in the following sections for the proposed development: aconservative approach based on shallow boreholes (i.e., boreholes less than 30 m in depth) with using localgeological/physiographical experience; and a method based on geophysical testing in accordance with the Section4.1.8.4 of the QBC.
It has been our experience that depending on the structural design requirements for structures that fall under theOBC jurisdiction, significant structural design and construction costs are frequently associated with the seismicdesign aspects. Significant cost savings may, therefore, be realized by adopting a more accurate site classificationmethod which can only be determined based on actual physical testing extending to a depth of at least 30 m belowthe ground surface. As such, we recommend that the methodology for the seismic testing of the site soils beselected in conjunction with discussions with the structural engineer for the project.
5.4.1 Conservative Approach
The conservative site classification is based on physical borehole information obtained at depths of less than 30 mand based on general knowledge of the local geology and physiography. Based on the results of our boreholes,the underlying soil conditions at the site generally consist of loose to compact flll overlying loose to dense sandysilt to silt. Based on the borehole information and our local experience, a preliminary Site Class E may be usedfor the building design.
5.4.2 Geophysical Method
To determine the actual site classification based on physical on-site measurements of shear wave velocity asrequired by OBC 2006, the Multichannel Analysis of Surface Waves (MASW) can be utilized. Should it be required
I :n Golder6/8 WAssociates
46 of 66
Mr. Mark Goulad 1544818 (13000)
Senior Project Coordinator November 30, 2016
by the structural engineer to optimize the Site Class for the development, MASW testing should be carried out at
the site.
5.5 Exterior Flatwork
It is understood that exterior concrete flatwork such as sidewalks may be required. The subgrade for exterior
concrete fiatwork should be inspected during construction to determine if it is capable of supporting the proposed
loads and to identify soft zones and areas of unsuitable subgrade soil. Therefore, during construction, the prepared
subgrade should be proofrolled in conjunction with an inspection by Colder. Remedial work shquld be carried out
on any softened, disturbed, wet or poorly performing zones as directed by Colder. Any low areas may then be
brought up to within at least 150 millimetres of the underside of the walkway slab, as required, using OPSS
Granular B, Type I or other approved non-frost susceptible material, placed in maximum 200 millimetres loose lifts
and uniformly compacted to at least 98 percent of standard Proctor maximum dry density (SPMDD).
The final lift of granular fill beneath concrete flatwork should consist of a minimum thickness of 150 millimetres of
OPSS Granular A, uniformly compacted to at least 98 percent of SPMDD. Any filling operations should be
monitored and tested by Colder.
5.6 General Considerations
All exterior footings and footings in unheated areas should be provided with at least 1.2 m of cover after final
grading, in order to minimize the potential for damage due to frost action.
Excavations for the proposed building must not encroach onto the zones of influence of any existing footings. The
zone of influence of a footing can be defined as any line drawn from the underside edge of the footing down and
away at 45° angles to the horizontal. Should there be any doubt regarding the potential for undermining the zone
of influence of any existing footings or structures by the proposed footings, Colder should be consulted to resolve
the conflict.
5.7 Testing and Inspection
During construction, foundation inspections, subgrade inspections and in-situ materials testing should be carried
out on site in order to confirm that the conditions exposed, are consistent with those encountered in the boreholes
and to monitor conformance to pertinent project specifications.
Colder7/8 Associates47 of 66
Mr. Mark Goularl 1544818 (13000)Senior Project Coordinator November 30, 2016
6.0 CLOSURE
We trust that this geotechnical information is sufficient for your current requirements. Should you have furtherquestions or comments, please do not hesitate to contact our office.
Yours Truly.
Golder Associates Ltd.
Rafael Abdulla, M.Eng., P.Eng., PMP Sarah EM. Poot, P.Eng.Geotechnical Engineer Associate, Senior Geotechnical Engineer
RNSEMP/ra lab
Attachments:Attachment A — Figures 1 and 2 Site Location Plan and Borehole Location PlanAttachment B — Method of Soil ClassificationAbbreviations and Terms Used on Records of Boreholes and Test Pits,List of SymbolsRecord of Borehole Sheets: BH16-1 to BH16-5Attachment C — Figures 3 and 4: Geotechnical Laboratory FiguresAttachment D — Important Information and Limitations of This Report
n:active\205i3 eroill 543816 crtyoftoronto geo.t&i parks to\p513000.donvalley golf. geoitepofls\15148 I 8 130001 cot don valley go gao let 2016’l 130 doca
:tGolder8/8 Associates
48 of 66
Mr. Mark Goulad 1544818 (13000)
Senior Project Coordinator November 30, 2016
Attachment AFigures 1 and 2 Site Location Plan and Borehole Location Plan
GoIderAssociates49 of 66
CONTOURS IM)ROADRAILWAY
UTILITY LINEWATER CO U R SEB U L-D NC
MUNICIPAL BOUNDARYWATER BODYWETLAND
WOODED AREA
GolderAssociates
PROJOfl NO16448 18)136001
OECiECIrOCA. Jvr_srsr1CIICCII VALLEY QOui ODUPSE SEPTORONTO 0111CR
RE FE RE N CEI S}NASE DATA MNR LID. OETA;NEO DOTEPRODUCED IT COLDER ASEOOATES LW UNDER UCENCE PROM ONTARIO MINISTRY OP NATURALRESOURCES. C QUEENS PRINTER TOTE
TRANEVERSE MERCATOR DATUM NW ED COORDINATE SYSTEM UTM ZONE ON 50 of 66
a,z0-JDLii
U5
—D
U,0
.jO<
oz
zw
-
0Z
LX(‘w
oo
00
—
0—z0LX0—Li.0
C>
C—
CU
z0.
zop<U0-JLi,
I
c.J
CCU
thIa,1)
U
*
CCC
CCC
CC
51 of 66
Ar. Mark Goulart 1544818 (13000)Senior Project Co-ardinalor November30. 2016
Attachment BMethod of ClassificationAbbreviations and Terms Used on Records of Borehoes andTest PitsList of Symbo’sRecord of Borehole Sheets: BHI6I to BHI6-5
@‘GoiderAssociates52 of 66
METHOD OF SOIL CLASSIFICATfON
The Goidcr 4ssociates Ltd Sol ClassifiCation System is based on the Uniftod Sot Ciassifcat on System (uSCS,
pe&SOn Cc
G a,e 5 Poortywith Graded
SI Or t3 GP GRAVEL00 a12%
——————-
————Ifines Wet Graded I to 3 GW GRAVEL
J:Bet ow A
I
wth Linen/a GM
GRAVEL‘12% —
fines Above A n/a GCCLAYEY
v macat LIne GRAVEL— — -I t30% —
Sands Poorlywith Graded
<6 51 or a3 SR SAND
t12% —-———-—---—— ——— ——--— —
rows %eIG’a,eo OS Ito: BAby nasaSands 5eVw A
ojC AM irema SI) SLT SAND
rar
bymass Low SAND
oc I Plaid in&at.
5m1t
Gresapi ItI N1A(cant
Rapid None None >5mm rot 3mm <S’u ML SILT
LiquidUmit —
.
<50Slow
Nfbeb0 Dull 3uit0 None to tow <5% ML CLAYEY SILT
-t Slowto Lowto Dutto 3mmto Low— 5%bo
CLORGANIC
g verystow medum stgtt 6mm 30% SILT
Q in Slowlo Lowso 3mmto Lowlo5 MH CLAYEY SILT
Is LqudLmtL51°’_jSt Smmrneeum <I
It asc Vetr a”o Irrrno Qedumlo 5uL C3-,C— N>ne or3, sql 3mm hgN 30
Cd
0 —-—-—-— ———-————-
L qsdLim None to01y . a CL S LTY CLAY
aOnin Lq.dLtm
Noneear ,QSJ I;rro
Medium an> c SLTY CLAY
- U see — —
E2 jo L fl None Hgn Sb n- <1mm high Note 2? Cii CLAY
—>-— L_ —
at peat and mreral sod° A SILTY PEAT
> matures SANDY PEATjZWcvun 75Ar>td m_mo 0 0 I? m I Predominantly peat
1 PT
‘ 00 2 E may oortain someu
I mineralsol fbrousor
Dual Symbol A dual symbol is two symbols separated
by a hyphen for example GP-GM SW-SC and CL-ML
For non Cohesive soils the dual symbols must be used
wt,en the soil has between 5% and 12% fines (i e to
identify transitional matenal between clean and dirty
sand or gravelFor cohesiVe soils the dual symbol must be used wt’en the
1a- liquid limit and plasticity index values plot in the CL-ML area
oF the plasticity chart (see Plasticity Chart at left)i
‘ i.vtAv BorderlIne Symbol — A borderline symbol is two symbols
I’ separated by a slash for example CL/Cl GM/SM CUML
A borderline symbol should be used to indicate that the soil
I’ L2 has been identified as having properties that are on the IIL ML inN vi transition between similar materials In addition a I
‘ e Se borderline symbol may be used to oc indicates a range ofbeid u—S Lu t ii r i’ • within r urn
Note I — Fine gnined materials with P1 and LI that plot in this area are named IMLI SiLT with sm a so ypes as a
aUght pbsticfty Fine grained materiais which are non piasiic (i e a PL cannot be nessared) arenamed SiLTNote 2— For soils with <5% organic content include the descriptor race organics for soils withbetween 5% and 30% organic content include the prent organic before the Primary name
Ca
cITv II.,
n
C Loyal sir Maneinluit silt ot
——‘[si 5. MH
rI>N!L S iT OK
76%to PEAT
GGOIdeFAssociatesJanuary 2013 G-153 of 66
Soil Particle Size Millim tinoises
Constituent Description ° °(US Std. Sieve Size)
BOULDERSpflble >300Js
COBBLES Not 75 to 300 3 1012Applicable
GRAVEL Coarse 19 1075 0 75 to 3Fine 475to19 (4)toO7S
Coarse 200 to475 (10) to (4)SAND Medium 0 425 do 200 (40) to (ID)
[ Fine 10.075 toO 425
SILT/CLAY Classtf:edby<0 075 < (200)
MODIFIERS FOR SECONDARY AND MINOR CONSTItUENTSPercentage
by Mass Modifier
Use and to comb:ne major constituents(I a. SAND and GRAVEL SAND and CLAY)
5 12 to 35 Primary soil name prefixed with ‘gravelly sandy. SILTYI CLAYEY as auplicabie
>5to12some
55 trace
PENETRATION RESISTANCEStansiarci Panelration Resistance SRI. N-The number of blows by a 635 kg (140 16) hammer dropped 760 mm (30 in.)required to drive a 50 mm (2 in.) split-spoon sampler for a distance of 300 mm(12 in.).
Cane Pe:aetration Test (CR1)An electronic cone penetrometer with a 60’ conical tip and a project end area of10 cm’ pushed through ground at a penetration rate of 2 cm/s Measurements oftip resistance (q1), porewater pressure (u) and sleeve frictions are recordedelectmnioaly at 25 mm penetration intervals
The number cf blows by a 535kg (140 Ib) hammer dropped 750mm (30 in todrive uncasea a 50 mm. (2 in ) diameter. 60’ cone allached bK sse dnll rods fora distance of 300 mm (12 in )PH: Sampler advanced by hydraulic pressurePM: Sampler advanced by manual pressureWH: Sampler advanced by static wetght of hammerWR: Sampler advanced by weigh: cf sampler and r
Compactnesst
Term SPT ‘N’ blowslo,3mVer Loose
4toioCom act 10 to 30
-5D
01566. uncorrected Icr
Temi Description
Dry Soil tows freely through fingers
Moist50:15 are darker than in the dry cond;ton andmay feel cool
v”eAsmost. but with free water form;ng on hands‘ when handled
GolderAssoctates
ABBREViATONS AND TERMS USED ON RECORDS OFBOREHOLES AND TEST PITS
PARTICLE SIZES OF CONSTITUENTS SAMPLES
AS • Auger sample
ES Block sample
CS Chunk sample
DO orSeamless open ended, driven or pushed tubesampler — note size
DS Denison type sample
FS Foil sample
RC Rock core
SC Soil core
55 Split spoon sampler— note s:ze
ST Slotted tube
TO Thin-walled, open — nole size
TP Thin-walled, piston — note size
V/S Wash sam.pe
SOIL TESTS
w water content
PL , w. plastic limit
LL . w l:quid limit
C - consoidabcn (oedometer) test.-.---— -----—
CHEM chemical anaiys:s (refer to tettlCID consolidated isotropicaily dra:ned trtaxial test
CIU consolidated isotropically undrained triaxial test withporewater pressure measuremenC
D relative density (specific gravity, Gs)
DS direct shear test
GS specific gravity
M sieve analysis for particle size
MH combined sieve and hydrometer (H) analysis
MPC Modified Proctor compaction test
SPC Standard Proctor compaction test
CC organic content test
SC . concentraton of water-solubie suiphates
bc . unccnt.ned compression test
UU unconsoi.idated undratned traxla: test
V (FV) field vane (LV-laboratory vane test)
y - unit weight
NON-COHESIVE (COHESIONLESS) SOILS
I Tests which are anisoopically consolidated pncr to shear areshown as CAD. CAU
COHESIVE SOILS
Consistency
I SPT ‘N in accordance with ASTftI overburdenpressure eltects.
2 Oetniticn of ccmpactnest descrpticns based on SRI N ranges trainTerzagni and Peck (1967) and correspond to typcal average N., values
Field Moisture Condition
TUndraIned Shear 1 SPTN’term
J/D3
y%___ <12 Oto2Soft 12to25 2to4Firm 2Sto5D 1 4toOStiff SOtolODi BtolS
Very Stiff 100 to 200 1 151030Hard >200 >30
sure5py in accorcance with ASTM 01586 unconecled for overburden pretetects approximate amy
Water Content
Term Description
Material is est:mated lobe drer than me PlasticwCPLLrnt
Mater;al is estimated to be close to tne PlasticLimit.
PLMateral is estmated to be weller than the PlasticLimit
January 2013 G-254 of 66
UST OF SYMBOLS
Unless otherwise stated, the symbols employed in the report are as follows:
II. STRESS AND STRAIN
shear straina change in, e.g. in stress: a a
linear strainvolumetric straincoefficient of viscosity
I.) Poisson’s ratioa total stressa’ effective stress (a’ a - u)a’ initial effective overburden stress. principal stress (major, intermediate.03 minor)
mean stress or octahedral stress= (as ÷ 02 + 03)/3shear stress
U porewater pressureE modulus of deformationG shear modulus of deformationK bulk modulus of compressibility
Ill. SOIL PROPERTIES
Index Propertiesbulk density (bulk unit weight)*
dry density (dry unit weight)density (unit weight) of waterdensity (unit weight) of solid particlesunit weight of submerged soil
(‘1 = y- yw)
relative density (specific gravity) of solidparticles (On = Ps / Pw) (formerly G)
e void ration porosityS degree of saturation
Density symbol is p. Unit weight symbol is ywhere y = pg (i.e. mass density multiplied byacceleration due to gravity)
(b) Hydraulic Propertiesh hydraulic head or potentialq rate of flowv velocity of flow
hydraulic gradientk hydraulic conductivity
(coefficient of permeability)seepage force per unit volume
(c) Consolidation (one-dimensional)C compression index
(normally consolidated range)Cr recompression index
(over-consolidated range)C5 swelling indexCa secondary compression indexm coefficient of volume change
coefficient of consolidationdirection)
ch coefficient of consolidationdirection)
T time factor (vertical direction)U degree of consolidation
pre-consolidation stressOCR over-consolidation ratio = O’p / 0’v
Shear Strengthpeak and residual shear strengtheffective angle of internal frictionangle of interface frictioncoefficient of friction tan 8effective cohesionundrained shear strength ( = 0 analysis)mean total stress (Cl + 03)12mean effective stress (Ci + 03)12(Ci - 03)12 or (al - 03)/2compressive strength (Ci - 03)
sensitivity
Notes: 1 :=c’+a’tano’2 shear strength = (compressive strength)12
I. GENERAL (a) Index Properties (continued)w water content
,t 3.1416 w1 or LL liquid limitIn x natural logarithm of x vip or PL plastic limitlog16 x or log x. logarithm of x to base 10 Ip or P1 plasticity index (wF — w5)g acceleration due to gravity w5 shrinkage limitt time IL liquidity index = (w — w) 1
Ic consistency index = (wr — w) / Iema* void ratio in loosest stateem16 void ratio in densest statelo density index = (emax — e) / (emax - emn)
(formerly relative density)
(a)
PCi)Pd(’fd)pw(yw)
Ps(l’s)
(vertical
(horizontal
(d)tp, tr
K4
c. sp
q
SI
t’’GoIderLd’AssodatesJanuary 2013 0-355 of 66
0
071
H
00
S
0
00OnccD0UIL
003-di
as
S09HSCasas0
0S“accSC0
IL
C03-di
as0’S090HSCccCH
C
0U,HSdi
UI,
PROJECT 1544518(13000) RECORD OF BOREHOLE: BHI6—1 SHEET 1 OF 1
LOCATION. See Figure 2 DATUM: GeodeticBORING DATE October 18, 2016
SPTIOCPT HAMMER: MASS, 64kg: DRCP, 760mm HAMMER TYPE AUTOMATIC
CCIHdi
0SccCdi
SOIL PROFILEdi
Co
s-El
C
DESCR:PTION
SAMPLES
HCIL
GROUND SURFACE
DEPTH(ml
ASPHALT (400mm)
5ciS0di
CXX
OYNAMIC PENETRATION HYDRAULIC CONEUCTIVITY,RESISTANCE, ELOWSiS3m ti, coWs
20 40 50 50 100 10’ 10’ IO
SHEAR STRENGTH nat V. + 0 - • WATER CONTENT PERCENTCu, tips rem V. I? U
WpF ‘A’ ‘WI
20 30 so so 10 20 30 40
FILL’ (SR’GP) SAND and GRAVELI BAS EAS U B BAS E IFILL - (MUSM) candy SILT to SILTYSAND, traCe to some gravel: brown,black stains, mats and mallets, woodfragments. non-cohesive, moist, loose tocompact
-JO<SZROw
0±
PIEZOM ST S NOR
STnIDPIPEINSTALLATION
.:141-.
1271? CA
as
55
FILL’ ISP/GP) SAND and GRAVEL,brown: non-cohesive, moist, Compact
325
0
El
H
55
(ML) sandy SILT, trace to smile gravel tograveily: grey: non-cohesive, wet, looseto compact
354
Coroosoe
Ce cnn DierneIsrPiesseeler
Evr?ovite
Naveeben 4. 20t5
SiIica Send tidIerand Screen
Cave
6 55 CI
so e
MH
NOTES:1, Borehole caved to a depth of about4.9 m below ground surface uponcompletion of drilling.
2. Groundwater level measured inborehole at a depth of about 3.7 m belowground surface upon completion ofditling,
3. Groundwater tevel measured inpiezometer at depth of about 3 S mbelow ground surface on November 4,2016,
DEPTH SCALE —. ‘
- Golder LOGGED: HS
1:50‘ Associates CHECKED TA
55 . Is
END OF OCR EHO LE122.22
ens
56 of 66
PROJECT: 1544018(13000) RECORD OF BOREHOLE: BH162 SHEET 1 OF I
LOCATION: See Figure 2BORING DATE: October 18 2016 DATUM: Geode(c
SPT/DCPT HAMMER: MASS, 84kg; DROP, 160mm HN1IMER TYPE: AUTOMATIC
CCS
34
‘3SSCC
CaC
S1’0
SAIELES DYNAAI/C PENETRATION HYDRAULIC CONDUCTIVITY.RESISTANCE. BLOWS/U 3m 0, (iWs
€3 IC’ 10’
SHEAR STRENCTh rat V — - .1 WATER CONTENT PERCENI’Cj,kPa re’rV- U-
CP!EZCt.IETER
ORS’nIDP FE
E/STALLAT.ON
SOIL PROFILE
CESCRIPT.tN
GROUND SURFACE
AS Ph/ALT ( lXm mlFILL (SP;GP) SAND and GRAVELBASE’S U B BAS E
FILL - INtSM) sandy SILT ID SILTYSAND; trace to are gravel. brcm.biack strs ‘,cod fragmentsncn-c&m*,e moist, loose 10 compact
(ML) SILT, some sand; grey;non-cohesive, wet, compact
(ML) soody SILT; grey. r,oacchesse,wet. bose to compact
3
S
IA -
ES 23
2 55 1
3 ES 5
4 Es 21
ES 13Se
5511
7 ES
5 55 23
ELEV
DEPTHm}
t34E
25
127,153-25
403
123(5
0 ,3 ;3 I3
Rn ;;- IWI
10 20 30 40
C
CC05
CC
aC03C
CCC4;
CC3.-Ed
C
SCCp2S
I
I7.32END OF BOREHOLE
NOTES:
5. Borehole caved to a depth of about4 6 m below groUnd suttaca uponcompletion of drIlling,
2 Grntstwater level meaasxed i,bot’ehde 03 a depth of abcut 4Dm beIravgrand sLface Lçfln comp/etlen ofddt ing
DEPTH SCALE LOGGED: HS
1 -50- Associates CHECKED: RA
57 of 66
PROJECT 1544618(13000) RECORD OF BOREHOLE: BHI6-3 SHEET 1 OF I
LOCATION. Sec Figure 2DOPING DATE October18. 2016 DATUM &odesc
SPTIDCRr RAMMER. MASS, 64kg. DRCP. leOmm HAMMER TYPE AUTOMATIC
— C SOIL pRorILE SAMPLES DYNAMIC PENETRATION HYDRAULIC CONDUCTIVITY. —
— Hob STmN c SLCWP 6C IET11P
ESCR P’ ON 4 R Wa OH a) 0 • OCr’ NP RLEN’
GROUND SURFACE I-
-
ASPFttTi10OnIrnlFILL• fSP;CP) SAND and GRAVEL(DASESUDRASCI
FILL. ISMI SILTY SAND. some gravel 19mm oame:evto gravelly brows, red beck fragments.non-cohesive moist loose lover1 dense
3 51
Augers gnrrding at a depth of about2 7 ml below ground surlace
I—. S..
O . 1O .U..
hr-ember 3.1016 U.4
.
.
(ML) sandy SILT, trace gravel; grey: 4114
so nDn-cohesve. wet, compact ID dense LISIsa Sand P11 Icr L1-
55
IENDOFILOREHOLE
U-
NOTES
I Groundwater to-jet measixed flel’roIe at a depTh of about 4 0 is belowground ssface upal completIon ofnlls,O
2 Gnurdwater level measured inpiezomeler at a depth of about 1 8 rnbelow ground surfaca cc November 42316
C—
High N-vaIue likely caused by beckobslroclions
05,—zw
U
0
____--
-_
DEPTHSCALE- :Golder LOGGED: IS
1.50 Associates CHECKED; RA
58 of 66
PROJECT: 1544518(13000) RECORD OF BOREHOLE: BHI6-4 SHEET I OF 1
LOCATION: See Figure 2BORING DATE Oclober 18, 2016
. 00 CC
SPT!DCPT HAMMER: MASS. 64kg: DROP. 760mm HMAMERTVPE. AUTOMATIC
— °OIL PROFILE SAMPLES DYNAMIC PENETRATION HYDRAULIC CONDUCTIVITY,C RESISTANCE, OLOWSID 3m k, cr,ils
<z PIEZOMETER
CE..CRPCNDPT
SHEARSTW” nary -Q AT RCrNTPRCENT 5 NSTALLATtN
CR0UC SURFACE 131252TOPSOILI200mm)
FILL - (SP) SAflD to gravefly SAnD. Dr
trace Io screw nal-Øaslic frees bm.Cnnalchewve. ndsl, compact to loose
1 ES II
2 SE 12
IAi2.i.1 .... ss 5
(ML) CEAYEY SILT, trace sand: grey: JJ 2.55 3e :1non-cohesive, moist to wet, flnilslilf I]
I Fr10
0Ii
0
- __ _.-____.
127Th
kiLl ssmth 5:11 grey: nc-c&.esrvi -
wet. colTcwe
a0LuU,
S S 55 20
CO 5U.
003-Lu
SOo
eirSS
__________
ENDOFBOREHOLE 655
NOTES:
1. Groundwater level measured inborehole at a depth of about 3.4 m below
O . ground surlace upon completion otdrilling.
003-
£ DEPTH SCALE LOGGED: HS
1 50 CHECKED:59 of 66
U,
.503
00>-uJ
.5
200
20
C0
LuU,
2
0C
003
3-
C>
2
0a2
3-
In
0
U,
FILL (SM) SILTY SAND. now-cohesive.moist, compact to loose
ML) sandy SILT. grey- ncn’coaesieea-el- compact
END OF 000ENOLE
NOTES:
1 Groundwater level measured LIlborehole at a depth of about 3 7 m belowground surface upon cmspletiorl ofdrilling.
0
‘2
C0
PROJECT 1544515(13000) RECORD OF BOREHOLE: BHI6-5 SHEET I OF 1
LOCATION: Soc Figure 2AT d ISORING DATE October 15, 2016 0 dv - Sea e ic
SPT-DCPTA1MER MASS, 54k; CROP ?SOmm S1.!MCR TYPE AUTOMATIC—
— vol. PRnr- 0 iFLrS C’vNA.ICPeNc:RA,ON HSERAaICC0ILCUCTLVITY-
— RES:STANCS BLOWS.’ 3m
CC
085 CR : P 7 10 N
CR0u1,o suRrecs
TDPSD)(T7snnl
FILL - -tILL CLAYCY SILT some sandbrown, roots and roollets non-cohesive.moist, compact
:LL
C
F 51C1.OTER
S TA N CF IFS
iN S ‘TA L L AT C N
(ML) CLAYEY SILT to SLT. trace to - -
some sand: grey: non- cohesive, moisl,loose to compact
—u sip
a,
55. 111
2:
S 05 I!
20
ELEV
DEPTh
- 010
1)153C)?
32555241
74
12475
5REAR5TREN0m nalV -‘ 0-•Cu kPa mmv -0-i -
10 17’ 10’ -‘
LLATER CONTENT PERCENT
20 30 CT
DEFTH SCALEGo1der LOGGED HS
1 50 CHECKED T
60 of 66
Mr. Mark Goulart 1544818 (13000)
Senior Project Coordinator November 30, 2016
Attachment CFigures 3 and 4: Geotechnical Laboratory Figures
®?coiderAssociates61 of 66
GRAIN SIZE DISTRIBUTION(ML) Gravelly Sandy SILT FIGURE 3
Size of Opefllfl;S. nones U SS Sewe s:ze meshesfnch
5’.. 3’ 1 1”. i 3S34 8’O IS OS :oo 5050 KS SOC
100
90
80.
. .70 I.
zIfr 50
UizU-50IzUio 40Ui0.
30
20
10
• . •0
100 10 1 01 0,01 0.001 0.0001
GRAIN SIZE, mm
COB&E COARSE F;NE COARSE MEOUM NE SILTANO CLAM szEs
SIZE GRAVEL SIZE SAND SIZE FINE GRAINED
LEG END
SYMBOL BOREHOLE SAMPLE DEPTH(m)
• 16-1 6 4.57-5.03
Project Number: 1544818 (13000)
Checked By: PA Golder Associates Date: 28-Nov-16
62 of 66
GRAIN SIZE DISTRIBUTION FIGURE 4
Size of openings, inches U S S Sieve size meshes/inch
54t 7 1W I ras 34 813 152030 405460 CD 15410G• I.e.’.
90
-
--
80 I
I
70z
60
LUz
50IzLU
40LU0-
30I
20
10 K
‘a. •C
100 10 1 01 001 0.001 0.0001
GRAIN SIZE, mm
CODDLE COARSE FINE COARSE MEDIUM FiNE SILTANOCSAYSIzES
SIZE GRAVEL SIZE SAND SIZE FINE GRAINED
LEGEND
SYMBOL BOREHOLE SAMPLE DEPTH(m)
• 16-5 5 4.57 -503• 16-3 6 6.10 -6.55
Project Number: 1544818 (13000)
Checked By: RA Golder Associates Date 28-Nov-16
63 of 66
Mr. Mark Goulart 1544818(13000)
Senior Project Coordinator November 30, 2016
Attachment 0important information and Limitations of This Report
®GolderAssociates64 of 66
IMPORTANT INFORMATION AND LIMITATIONS OF THIS REPORT
Standard of Care: Colder Associates Ltd (Colder) has prepared this report in a manner consistent with thatlevel of care and skill ordinarily exercised by members of the engineering and science professions currentlypractising under similar conditions in the junsdiction in which the services are provided, subject to the time limitsand physical constraints applicable to this report No other warranty, expressed or implied is made
Basis and Use of the Report: This report has been prepared for the specific site, design objective,development and purpose described to Colder by the Client The factual data, interpretations andrecommendations pertain to a specific project as described in this report and are not applicable to any otherproject or site location Any change of site conditions, purpose, development plans or if the project is not initiatedwithin eighteen months of the date of the report may alter the validity of the report Colder can not beresponsible for use of this report, or portions thereof, unless Colder is requested to review and, if necessary,revise the report
The information, recommendations and opinions expressed in this report are for the sole benefit of the Client Noother party may use or rely on this report or any portion thereof without Colder’s express wntten consent If thereport was prepared to be included for a specific permit application process, then upon the reasonable requestof the client, Colder may authorize in writing the use of this report by the regulatory agency as an Approved Userfor the specific and identified purpose of the applicable permit review process Any other use of this report byothers is prohibited and is without responsibility to Colder The report, all plans, data, drawings and otherdocuments as well as all electronic media prepared by Colder are considered its professional work product andshall remain the copynght property of Colder, who authorizes only the Client and Approved Users to makecopies of the report, but only in such quantities as are reasonably necessary for the use of the report by thoseparties The Client and Approved Users may not give, lend, sell, or otherwise make available the report or anyportion thereof to any other party without the express written permission of Colder The Client acknowledges thatelectronic media is susceptible to unauthorized modification, deterioration and incompatibility and therefore theClient can not rely upon the electronic media versions of Colder’s report or other work products
The report is of a summary nature and is not intended to stand alone without reference to the instructions givento Colder by the Client, communications between Colder and the Client, and to any other reports prepared byColder for the Client relative to the specific site described in the report In order to properly understand thesuggestions, recommendations and opinions expressed in this report, reference must be made to the whole ofthe report Colder can not be responsible for use of portions of the report without reference to the entire report
Unless otherwise stated, the suggestions, recommendations and opinions given in this report are intended onlyfor the guidance of the Client in the design of the specific project The extent and detail of investigations,including the number of test holes, necessary to determine all of the relevant conditions which may affectconstruction costs would normally be greater than has been carried out for design purposes Contractors biddingon, or undertaking the work, should rely on their own investigations, as well as their own interpretations of thefactual data presented in the report, as to how subsurface conditions may affect their work, including but notlimited to proposed construction techniques, schedule, safety and equipment capabilities
Soil, Rock and Groundwater Conditions: Classification and identification of soils, rocks, and geologic unitshave been based on commonly accepted methods employed in the practice of geotechnical engineering andrelated disciplines Classification and identification of the type and condition of these materials or units involvesjudgment, and boundaries between different soil, rock or geologic types or units may be transitional rather thanabrupt Accordingly, Colder does not warrant or guarantee the exactness of the descriptions
ii Golder2013 1 of 2 WAssonates65 of 66
IMPORTANT INFORMATION AND LIMITATIONS OF THIS REPORT
Special risks occur whenever engineering or related disciplines are applied to identify subsurface conditions andeven a comprehensive investigation, sampling and testing program may fail to detect all or certain subsurfaceconditions. The environmental, geologic, geotechnical, geochemical and hydrogeologic conditions that Golderinterprets to exist between and beyond sampling points may differ from those that actually exist. In addition tosoil variability, fill of variable physical and chemical composition can be present over portions of the site or onadjacent properties, The professional services retained for this project include only the geotechnical aspects ofthe subsurface conditions at the site, unless otherwise specifically stated and identified in the report. Thepresence or implication(s) of possible surface and/or subsurface contamination resulting from previous activitiesor uses of the site and/or resulting from the introduction onto the site of materials from off-site sources areoutside the terms of reference for this project and have not been investigated or addressed.
Soil and groundwater conditions shown in the factual data and described in the report are the observedconditions at the time of their determination or measurement. Unless otherwise noted, those conditions form thebasis of the recommendations in the report. Groundwater conditions may vary between and beyond reportedlocations and can be affected by annual, seasonal and meteorological conditions, The condition of the soil, rockand groundwater may be significantly altered by construction activities (traffic, excavation, groundwater levellowering, pile driving, blasting, etc.) on the site or on adjacent sites. Excavation may expose the soils to changesdue to wetting, drying or frost, Unless otherwise indicated the soil must be protected from these changes duringconstruction.
Sample Disposal: Golder will dispose of all uncontaminated soil and/or rock samples 90 days following issue ofthis report or, upon written request of the Client, will store uncontaminated samples and materials at the Client’sexpense. In the event that actual contaminated soils, fills or groundwater are encountered or are inferred to bepresent, all contaminated samples shall remain the property and responsibility of the Client for proper disposal.
Follow-Up and Construction Services;.All details of the design were not known at the time of submission ofGolder’s report. Golder should be retained to review the final design, project plans and documents prior toconstruction, to confirm that they are consistent with the intent of Golder’s report.
During construction, Golder should be retained to perform sufficient and timely observations of encounteredconditions to confirm and document that the subsurface conditions do not materially differ from those interpretedconditions considered in the preparation of Golder’s report and to confirm and document that constructionactivities do not adversely affect the suggestions, recommendations and opinions contained in Golder’s report.Adequate field review, observation and testing during construction are necessary for Golder to be able to provideletters of assurance, in accordance with the requirements of many regulatory authorities. In cases where thisrecommendation is not followed, Golders responsibility is limited to interpreting accurately the informationencountered at the ‘borehole locations, at the time of their initial determination or measurement during thepreparation of the Report.
Changed Conditions and Drainage: Where conditions encountered at the site differ significantly from thoseanticipated in this report, either due to natural variability of subsurface conditions or construction activities, it is acondition of this report that Golder be notified of any changes and be provided with an opportunity to review orrevise the recommendations within this report. Recognition of changed soil and rock conditions requiresexperience and it is recommended that Golder be employed to visit the site with sufficient frequency to detect ifconditions have changed significantly.
Drainage of subsurface water is commonly required either for temporary or permanent installations for theproject. Improper design or construction of drainage or dewatering can have serious consequences. Goldertakes no responsibility for the effects of drainage unless specifically involved in the detailed design andconstruction monitoring of the system.
20132 of 2 Associates
66 of 66