document no. 31629-13-rpt-0004 rev. a · document no. 31629-13-rpt-0004 rev. a page a13 of a14...

Document No. 31629-13-RPT-0004 Rev. A

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Figure A-7. Soil-Nailed Wall Excerpt from FHWA-SA-96-038


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ATTACHMENT B. MINUTES OF MEETINGS


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Figure B-1. Minutes of Meeting on 5/19/16


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ATTACHMENT C. EMAILS:


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ATTACHMENT D. CIVIL PLAN OF EXCAVATION WITH PROPOSED EARTH RETAINING SYSTEM


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Figure D-1. Civil Plan and Section with Proposed Earth Retaining System


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Figure D-2. Section through Soldier Pile Earth Retaining System


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ATTACHMENT E. CONCEPTUAL DESIGN EXCAVATION PLAN


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Figure E-1. Conceptual Design Excavation Plan and Sections


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ATTACHMENT F. EXCAVATOR USED IN ERS CALCULATIONS


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Figure F-1. Excavator Specifications


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ATTACHMENT G. ERS CALCULATIONS


Shoring System Calculations

ReferencesCalifornia Shoring and Trenching Manual, 2011.1.Das, Braja, "Principles of Geotechnial Engineering", Fourth Edition, 1997.2.AISC Steel Construction Manual, 14th Edition.3.FHWA-IF-99-015, "Ground Anchors and Anchored Systems", Geotechnical Engineering Circular No. 4, June4.1999.Final Report Geotechnical Investigation: River Protection Project-Waste Treatment Plant...200 East Area,5.Hanford Site, Richland, Washington, May 11, 2000.WRPS-1505215, Interoffice Memorandum. "Geotechnical Consultant Letter of Recommendation". Washington6.River Protection Solutions, Dated November 10, 2015.

Soil Properties

γ 120pcf Soil unit weight. Conservative, for Fig. 8-1, Ref. 5, forDune Sand and Hanford Formation Sand Facies LowerSand. See Ref. 6 that allows using Ref. 5.

ϕ 32deg Angle of internal friction. See email from Clint Wilsondated 6/7/16 in Attachment D.

δ 17deg Angle friction between steel pile and sandy soil per 2011California Shoring and Trenching Manual, Table 4-2

β 0deg Slope of soil.

ω 0deg Angle of face of retaining wall. See 2011 CaliforniaShoring and Trenching Manual, Figure 4-7, page 4-15.

Find coefficient of active pressure above the excavated soil using Rankin's Theory, which conservatively ignoresthe effect of wall friction. See Das (1997), Eq. 10.17, page 441.

Ka1 tan 45deg 0.5 ϕ( )2

0.307 Coefficient of active earth pressure.

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Find coefficient of active pressure using Coulomb's Theory. See 2011 California Shoring and Trenching Manual,Eq. 4-20, page 4-15. See Figure 1 for definition of parameters.

Ka2cos ϕ ω( )

2

cos ω( )2cos δ ω( ) 1

sin δ ϕ( ) sin ϕ β( )

cos δ ω( ) cos ω β( )

2

0.277

Figure 1 Notation used to determine Coulombs active pressure coefficient

Find passive pressure coefficient using 2011 California Shoring and Trenching Manual, Figure 4-37

δ

ϕ0.531

β

ϕ0

R 0.75 Reduction factor based on δ

ϕ0.531

Kp 9.3 Coefficient of passive earth pressure before reductionfrom 2011 California Shoring and Trenching Manual,Figure 4-37. See Figure 2

Kph Kp R cos δ( ) 6.67

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Figure 2 Passive earth pressure coefficient from California Shoring and Trenching Manual, Figure 4-37

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Anchor Vertical Spacing and Depth of Excavation

S1 7ft Spacing of top anchor

S2 15ft Spacing of second anchor

S3 15ft Spacing of third anchor

S4 7ft Vertical distance between third anchor and final bottom ofexcavation.

H1 S1 3ft 10 ft Excavation depth before first anchor installation.Excavation is 3 ft deeper than anchor for anchorinstallation.

H2 S1 S2 3ft 25 ft Excavation depth before second anchorinstallation.Excavation is 3 ft deeper than anchor foranchor installation..

H3 S1 S2 S3 S4 44 ft Excavation depth before third anchor installation.

Surcharge Loading Due to Equipment

The surcharge loading due to trucks next to the wall will be determined.

The Boussinesq solution for lateral pressure on a wall due to a point load as given in the California Trenching andShoring Manual, page 4-74, is used. x is the distance from the point load to the wall measured parallel to the wall.y is the horizontal distance from the point load to the wall measured perpendicular to the wall. z is the distancefrom the point load elevation to the elevation along the wall where the pressure is determined.

y

H LATERALPRESS.LOCATION

Qp

z

Figure 3 Section for lateral pressure calculation due to a point load.

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θ1 x y( ) atan

x

y

Angle. See California Trenching and Shoring Manual,Figure 4-51, page 4-75.

σh_Qp x y z H Qp 0.28Qp

H2

z

H

2

cos 1.1 θ1 x y( ) 2

0.16z

H

2

3

y

H0.4if

1.77Qp

H2

y

H

2z

H

2

cos 1.1 θ1 x y( ) 2

y

H

2z

H

2

3

y

H0.4if

Ref. 1, Eq. 4-70.

Ref. 1, Eq. 4-71

Minimum Construction Surcharge Load

σh_min 75psf Minimum construction surcharge recommended by theCalifornia Trenching and Shoring Manual, Sect. 4.8.1,page 4-70.

Worst case is due to an excavator. The potential excavator surcharge loads are due to a Caterpillar 352F,2015 CAT Catalog AEHQ7476-01 (12/2015) model R4.3TB HD (14'1")

Figure 4 Plan of loading due to excavator.

Woperating 116.6kip Operating Weight

Ltrack 14ft 3in Track length (max).

strack 9ft 6in Spacing of tracks measured between track centerlines.

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wtruck

Woperating

2 Ltrack4.091 klf Line loads at both tracks.

Lclear 5ft Closest distance from track centerline of excavator towall.

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Surcharge Loading Before First Tie Back Installation

H1 10 ft Excavation depth before first anchor installation,calculated previously.

σh_truck_1 z( )

0.5 Ltrack

0.5 Ltrack

xσh_Qp x Lclear z H1 wtruck σh_Qp x Lclear strack z H1 wtruck

d

σh_truck_1 z( ) if z 10ft max σh_truck_1 z( ) σh_min σh_truck_1 z( )

j 0 10

Zj

j ft

0 0.1 0.2 0.3 0.410

8

6

4

2

0

Zj

σh_truck_1 Zj ksf

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Surcharge Loading Before Second Tie Back Installation

H2 25 ft Excavation depth before second anchor installation,calculated previously.

σh_truck_2 z( )

0.5 Ltrack

0.5 Ltrack


d


j 0 25

Zj

j ft

0 0.05 0.1 0.15 0.230

20

10

0

Zj

σh_truck_2 Zj ksf

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Surcharge Loading Before Third Tie Back Installation

H3 44 ft Excavation depth after third anchor installation,calculated previously.

σh_truck_3 z( )

0.5 Ltrack

0.5 Ltrack


d


j 0 46

Zj

j ft

0 0.02 0.04 0.06 0.0850

40

30

20

10

0

Zj

σh_truck_3 Zj ksf

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Adjusted Pile Width and Spacing

It has been shown that the adjusted pile width is greater than the the effective pile width due to soil arching. See2011 California Shoring and Trenching Manual, Sect. 6.2.

d 15.7in Effective pile width for an HP16x88 section.

arch_cap_factor min 0.08ϕ

deg 3

2.56 Arching Capability Factor per 2011 California Shoring andTrenching Manual, Table 6-1.

d1 d arch_cap_factor 3.349 ft Adjusted pile width per 2011 California Shoring andTrenching Manual, Eq. 6-1.

s 8ft Soldier pile spacing.

Condition Before Top Anchor Installation

This is the condition before the top anchor has been installed.

H1 10 ft The depth to the bottom of excavation before the topanchor is installed, calculated previously.

Figure 5 Elevation of soldier pile wall before first anchor installation.

Find the active and passive pressure distributions,

σa1 z( ) Ka1 γ z Active pressure above excavation depth.

σa2 z( ) Ka2 γ z Active pressure below excavation depth.

wa z( ) s( ) σa1 z( ) σh_truck_1 z( )

d1 σa2 z( ) σh_truck_1 z( ) z H1if

Total active pressure and surcharge loading applied tosoldier pile.

wp z( ) 0klf

d1 Kph γ z H1 z H1if

Total passive pressure loading applied to soldier pile.

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j 0 20

Zj

j

20

2 H1

0 1 2 3 4 5

20

10

0

Zj

ft

wa Zj klf

0 10 20 30

20

10

0

Zj

ft

wp Zj klf

Driving moment about bottom of pile.

MD D( )

0ft

H1 D

zwa z( ) H1 D z

d

Resisting moment about bottom of pile.

Resisting moment about bottom of pile.MR D( )

0ft

H1 D

zwp z( ) H1 D z

d

FS 1.3 Required safety factor per 2011 California Shoring andTrenching Manual, page 6-17.

Msum D( ) MR D( ) FS MD D( ) Function to represent unbalanced moment betweenresisting and driving moment.

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Plot Msum,

j 0 20

DDj

j ft

1 103 0 1 10

3 2 103

0

5

10

15

20

DDj

ft

Msum DDj kip ft

Find the required embedment depth, D, by iteration so that Msum is zero.

D 13.14ft

Msum D( ) 0.55 kip ft ~ 0 OK.

Ddesign 1.2 D 15.768 ft Increase the embedment depth as required by Ref. 1,page 6-3.

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Find sheet pile moment and shear force diagrams,

Vfunc Z( )

0ft

Z

zwa z( ) wp z( )

d

Mfunc Z( )

0ft

Z

zwa z( ) wp z( ) Z z( )

d

N 40 j 0 N Zj

H1 D

Nj( )

400 200 0 200 40030

20

10

0

Zj

ft

Mfunc Zj kip ft

200 100 0 10030

20

10

0

Zj

ft

Vfunc Zj kip

Find maximum pile moment and shear force. The maximum moment and shear force are determined abovewhere the shear force is zero and the moment is maximum since the simplified method used in the CaliforniaShoring and Trenching Manual does not represent the actual moment and shear force below this depth. Thiscan be observed since the moment and shear force should be zero at the bottom of the pile. Inspection of theplots above show that the simplified method does not meet this condition.

Find maximum moment where V = 0 by iteration,

Zmax 15.9ft

Vfunc Zmax 0.898 kip

Mmax Mfunc Zmax 298.071 kip ft

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Find maximum shear which occurs above the elevation Z = 16 ft

N 40 j 0 NZj

16ft

Nj( )

Vj

Vfunc Zj

Vmax max V V( ) 35.669 kip

10 0 10 20 30 4020

15

10

5

0

Zj

ft

Vj

kip

Summary

Maximum Pile Moment and Shear Force

Mmax 298.071 kip ft Vmax 35.669 kip

Check moment and shear capacity,

Fy 50ksi Pile yield strength. ASTM A572, Gr. 50

Mu 1.6Mmax 476.913 kip ft

Zreq

Mu

0.9 Fy127.177 in

3

ZHP16x88 161in3

Note this shape exceeds compact limit for flexure with Fy= 50 ksi. Check actual capacity using AISC 14th Ed,Sect. F3.

DCZreq

ZHP16x880.79 < OK.

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Check shear per AISC 14th Ed, Sect. G2

ϕv 0.9

dHP16x88 15.3in

tw_HP16x88 0.540in

Aw dHP16x88 tw_HP16x88 8.262 in2

Cv 1.0

ϕVn ϕv 0.6 Fy Aw Cv 223.074 kip

Vu 1.6 Vmax 57.07 kip

DCVu

ϕVn0.256 < 1.0 OK

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Condition When All Anchors Have Been Installed

H H3 44 ft Final depth of excavation.

Find the active pressure for braced/restrained walls per the 2011 California Trenching and ShoringManual, page 7-2,

P 0.5 Ka1 γ H2

35.691kip

ft

pa1.3P

HS1

3

S4

3

1.18 ksf Maximum active pressure pressure. Ref. 1, Eq.7-3.

σa z( ) pa

paz

2S1

3

z2S1

3if

paH z( )

2 S4

3

z H2 S4

3if

Ka2 γ z z Hif

Force on pile using pressure distribution accordingFigure 7-2, 2011 California Trenching and ShoringManual, page 7-2.

j 0 40

Zj

j 1.5 H

40

0 1 2 380

60

40

20

0

Zj

ft

σa Zj ksf

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Find the resultant of the active pressure and surcharge loading.

s 8 ft Pile spacing defined previously.

d1 3.349 ft Adjusted pile width determined previously.

wa z( ) s σa z( ) σh_truck_3 z( )

d1 σa z( ) σh_truck_3 z( ) z Hif

Note that active pressure is multiplied by the pilespacing above the excavation and by the adjusted pilewidth below the excavation.

0 2 4 6 8 10 1280

60

40

20

0

Zj

ft

wa Zj klf

Find the passive pressure,

wp z( ) 0klf

d1 Kph γ z H3 z Hif

Total passive pressure and surcharge loading applied tosoldier pile.

Find the first anchor force per the California Trenching and Shoring Manual page 7-11.

M10

S1

zwa z( ) S1 z

d 126.021 kip ft

T1U0

S1

zwa z( )

d 48.239 kip

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T1LS1

S1 0.5 S2

zwa z( )

dM1

S2 83.639 kip

T1 T1U T1L 131.878 kip

Find the second anchor force per the California Trenching and Shoring Manual page 7-11.

T2US1 0.5 S2

S1 S2

zwa z( )

dM1

S2 66.01 kip

T2LS1 S2

S1 S2 0.5 S3

zwa z( )

d 72.904 kip

T2 T2U T2L 138.914 kip

Calculate last (third) anchor force per the California Trenching and Shoring Manual page 7-11.

T3U T2L 72.904 kip

Find the embedment depth Dp by setting the driving moment equal to resisting moment. Moments are calculated

about the last (third) anchor.

MD Dp S1 S2 S3

H3 Dp

zwa z( ) z S1 S2 S3

d

MR Dp H3

H3 Dp

zwp z( ) z S1 S2 S3

d

Msum Dp MR Dp MD Dp

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Plot Msum,

j 0 10

DDj

j ft

500 0 500 1 103 1.5 10

30

2

4

6

8

10

DDj

ft

Msum DDj kip ft

Find the required embedment depth, Dp, by iteration so that Msum is zero.

Dp 5.1565ft

Msum Dp 3.558 103

kip ft ~ 0 OK.

T3LS1 S2 S3

H3 Dp

zwa z( ) wp z( )

d 35.883 kip

T3 T3L T3U 108.787 kip

T3 107.6kip Provides for better equilibrium, see pile shear force andmoments below.

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Find design pile embedment D by using a factor safety of 1.3,

FS 3

Msum D( ) MR D( ) FS MD D( )

Plot Msum,

j 0 15

DDj

j ft

1 103 500 0 500 1 10

30

5

10

15

DDj

ft

Msum DDj kip ft

Find the required embedment depth, D, by iteration so that Msum is zero.

D 12.41ft

Msum D( ) 0.093 kip ft ~ 0 OK.

USE D = 13 ft

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Plot sheet pile shear and moment diagram,

u z( ) if z 0 0 1( ) Define unit step function

V1 Z( )

0

Z

zwp z( ) wa z( )

d T1 u Z S1 T2 u Z S1 S2 T3 u Z S1 S2 S3

M1 Z( )

0

Z

zwp z( ) wa z( ) Z z( )

d T1 Z S1 u Z S1 T2 Z S1 S2 u Z S1 S2

T3 Z S1 S2 S3 u Z S1 S2 S3

j 0 100

Zj

jH3 Dp

100

Vj

V1 Zj M

jM1 Z

j M1 H3 Dp 1.462 kip ft V1 H3 Dp 0.245 kip

100 50 0 50 10050

40

30

20

10

0

Zj

ft

Vj

kip

200 100 0 100 200 30050

40

30

20

10

0

Zj

ft

Mj

kip ft

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Mmax max M M( ) 274.703 kip ft Vmax max V V( ) 79.89 kip

Check moment and shear capacity,

Fy 50ksi Pile yield strength.

Mu 1.6Mmax 439.525 kip ft

Zreq

Mu

0.9 Fy117.207 in

3

ZHP16x88 161in3

Note this shape exceeds compact limit for flexure with Fy= 50 ksi. Check actual capacity using AISC 14th Ed,Sect. F3.

DCZreq

ZHP16x880.728 < 1.0

OK.

Check shear per AISC 14th Ed, Sect. G2

ϕv 0.9

dHP16x88 15.3 in Section depth, previously defined.

tw_HP16x88 0.54 in Section web thickness, previously defined.

Aw dHP16x88 tw_HP16x88 8.262 in2

Cv 1.0

ϕVn ϕv 0.6 Fy Aw Cv 223.074 kip

Vu 1.6 Vmax 127.824 kip

DCVu

ϕVn0.573 < 1.0 OK

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Design Anchors

Anchor tendons are of the capacity

ϕTn_min 260kN 58.45 kip Typical minimum anchor design load per Ref. 4, page 70.

ϕTn_max 1160kN 260.778 kip Typical maximum anchor design load per Ref. 4, page 70.

The bond length is between 4.5 m and 12 m per Ref. 4, page 70,

Lbond_min 4.5m 14.764 ft

Lbond_max 12m 39.37 ft

Shannon and Wilson recommended using values in Table 6, FWHA-IF-99-015, for ultimate transfer load (bondstrength) for Sand, Medium Dense to Loose. The value for Loose Sand will be used.

ρ 100kN

m6.852

kip

ft

θ 15deg Inclination of tie-back with respect to horizontal.

Tmax1

cos θ( )max T1 T2 T3 143.814 kip

Tu 1.6 Tmax 230.103 kip Factored tie-back force using a 1.6 load factor.

Lbond_req

Tu

ρ33.581 ft

USE Lbond = 34 ft.

The bonded length must extend beyond the active failure plane which is at an angle of 45 deg + ϕ/2 from the

horizontal by a minimum of H3

58.8 ft or 1.5m 4.921 ft Conclusion: One tie-back per soldier pile is required.

The anchor can be directly supported by the soldier pile or it can be supported by walers between the soldierpiles..

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Design of Walers

s 8 ft Spacing of the soldier piles.

Fy 36ksi Yield strength of walers (channel sections)

Mu

Tu s

4460.206 kip ft

Zreq

Mu

2 Fy76.701 in

3 Section modulus required for double channels

back-to-back.

ZMC18x51.9 87.3in3

DCZreq

ZMC18x51.90.879 < 1.0 OK.

Use MC 18x51.9 walers.

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document no. 31629-13-rpt-0004 rev. a · document no. 31629-13-rpt-0004 rev. a page a13 of a14...

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