Rock Socket EC 7 Template- Rev 00
Transcript of Rock Socket EC 7 Template- Rev 00
PRESTEDGE RETIEF DRESNER WIJNBERG (PTY) LTD
CONSULTING PORT AND COASTAL ENGINEERS
PROJECT 1096 Matola TCM - FEL 3 DATE 4/7/2023 SHEET # 01 of 01
ISSUED BY SIGNED DATE SECTION
DESIGN WGD DRAWING REF. 1096/00/5040 and 1096/00/5100
CHECKED SAH MODEL REF. NA
APPROVED PES CALC # 1096|Socket Ø 1016 Piles|001 Rev 00
CALC FILE REF. X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\WGD\4. Calculations
MODEL FILE REF.
Group Effects Must be considered for a centre to centre spacing less than 4 diameters between pile shafts for axial loads and 5 diameters for lateral loads
Design of rock sockets for tubular steel piles
Check 1. Axial loading (Compression and Tension)
Check 2. Lateral Loading
Input Calculation Note
Design of rock sockets to LRFD using FHWA, 2010 - Drilled Shafts: Construction procedures and LRFD design methods
In accordance with extracts from Tomlinson
Lateral checks conducted using Lpile v 6.0 from Ensoft
Pile Reference Pile Group Ø 1016 x 18wt Piles
Critical Pile D4 (Comp) & D3 (Lat)
Position (in x) All 1016mm Piles
Rock Level -18.5 m MSLCritical Load Combination
Raked (Y/N) N
Tubular Steel Pile
Outside Diameter D 1.0160 m See sketch below
Wall Thickness t 0.0180 m
Level at top of pile z1 1.70 m MSL
Sea bed level z2 -18.50 m MSL
Raking angle a 0.24 RAD
Rock Socket
Socket Length Ls 6.50 m
Socket outside diameter Ds 0.90 m
Penetration depth Pd 3.00 m
Steel
Elastic Modulus Steel Es 210000 MPa
Steel yield Strength Fy 350 MPa
Unit weight of steel g steel 77
Concrete
Elastic Modulus Concrete Ec 20000 MPa
Concrete Strength fc 45 MPa
Unit weight of reinforced concrete γ concrete 25
Rock
Rock UCS (average over socket) 2.00 MPa
RQD (average over socket) RQD 60.0%
Unit weight of rock y rock 20
Loading
Working Ultimate
Axial Compression (Reactions for Prokon Model) PDE 2238 3003 kN
Axial Tension (Reactions from Prokon Model) TDE 1 1 kN
Momets load cases included under the lateral load checks
Socket Sizing - Ø 1016 x 18wt Piles
X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\DJP\2. Design\Prokon Models\Phase 4A - 4B loading\Final - incl. add. Rakers\1096 - 4A Berth 4B Loads - 2012-03-21 - API Rev01.A03
Calculation Description
→ Initial sizing of pile (Ø governed by casing Ø length governed by loading and geotechical axial resistance - ULS case and SLS case
→ Use Initial sizing from Check 1. Calculate RC pile axial load bending moment interaction curves (use Lpile), factor interaction curves by LRFD structural resistance factors, calculate geotechnical lateral resistance using LPile input LRFD factored loads factored again by the geotechnical lateral resistance factor and check that pile response does not exceed the factored interaction curves allowable bending moment for associated vertical loads. ULS case and SLS case
Spreadsheet Notation
Governing Code Reference
Member Dimensions
Material Properties
kN/m³
kN/m³
quc
kN/m³
Design Checks
Rock Socket Design Checks Criteria Reference Results
Axial Compression
Rock Socket Shaft Friction 0.94 OK
Settlement under axial loading 3.82 mm
Axial Tension
Rock Socket Pull Out Resistance 0.00 OK
Rock Socket Shaft Friction 0.00 OK
Rock Socket Design Checks Criteria Reference Results
Lateral Loading
Casing Factored Moment Resistance OK OK
Socket Factored Moment Resistance OK OK
Deflection at ULS 0.0036 OK
Typical Section
Condition Status
ρ < 25mm
Condition Status
ρ < 10% shaft Ø
Steel tubular pile - length varies
Pile Cap - Pile Concrete ConnectionLconpp | Lconsk
Penetration depth (2-3m) (Pd)
Rock socket - length varies (Ls)
Rock socket
Socket- Pile Concrete ConnectionLconpp | Lconsk
Insitu concrete
Insitu concrete
Precast pile cap
Rock level
D
t
z1
z2
Ds
PRESTEDGE RETIEF DRESNER WIJNBERG (PTY) LTD
CONSULTING PORT AND COASTAL ENGINEERS
PROJECT 1096 Matola TCM - Phase 4 - FEL 3 DATE 4/7/2023 SHEET # 01 of 01
ISSUED BY SIGNED DATE SECTION Socket Sizing - Ø 1016 x 18wt Piles
DESIGN WGD DRAWING REF. 1096/00/5040 and 1096/00/5100
CHECKED SAH MODEL REF. NA
APPROVED PES CALC # 1096|Socket Ø 1016 Piles|001 Rev 00
CALC FILE REF. X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\WGD\4. Calculations
MODEL FILE REF. X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\DJP\2. Design\Prokon Models\Phase 4A - 4B loading\Final - incl. add. Rakers\1096 - 4A Berth 4B Loads - 2012-03-21 - API Rev01.A03
CHECK 1. Design of rock socket for compression and tenison loading - Based on Tomlinson and FHWA, 2010
Input Calculation Note
Tomlinson's
FHWA, 2010 - Drilled Shafts: Construction Procedures and LRFD Design Methods
Pile Reference Pile Group Ø 1016 x 18wt PilesCritical Pile D4 (Comp) & D3 (Lat)Position (in x) All 1016mm PilesRock Level -18.5 m MSL
Critical Load Combination 0Raked (Y/N) N
Outside Diameter D 1.016 m
Wall Thickness t 0.018 m
Level at top of pile z1 1.70 m MSL
Sea bed level z2 -18.50 m MSL
Raking angle a 0.24 RAD
Socket Length Ls 6.50 m
Socket outside diameter Ds 0.90 m
Penetration depth Pd 3.00 m
Section PropertiesInside Diameter d 0.98 m
Steel area AS 0.056
Total plug area AT 0.754
Moment of Inertia I 0.007
Elast. Sect. Mod. Ze 0.014
Plast. Sect. Mod. Zp 0.018
Radius of Gyration r 0.353 m
Elastic Modulus Steel Es 210000 MPa
Steel yield Strength Fy 350 MPa
Unit weight of steel g steel 77
Elastic Modulus Concrete Ec 20000 MPa
Concrete Strength fc 45 MPa
Unit weight of reinforced concrete γ concrete 25
Rock UCS 2.00 MPa
RQD RQD 60%
Unit weight of rock y rock 20.00
Loading
Working Ultimate
Axial Compression (extreme environmental conditions) PDE 2238 3003 kN
Axial Tension (extreme environmental conditions) TDE 1 1 kN
Design ChecksRock Socket Axial Loading Checks Criteria Reference Results Condition Status
Axial Compression
Rock Socket Shaft Friction 0.94 OK
Settlement under axial loading 3.82 mm
Axial Tension
Calculation Description
Spreadsheet Notation
Governing Code Reference
Member Dimentions
m²
m²
m⁴
m³
m³
Material Properties
kN/m³
kN/m³
quc
kN/m³
ρ < 25mm
Rock Socket Pull Out Resistance 0.00 OK
Rock Socket Shaft Friction 0.00 OK
ROCK SOCKET DESIGN
Axial Compression
Rock Socket Shaft Friction - ultimate bond stress between socket concrete and rock
- From Tomlinson - Equ: 4.25
- LRFD design factors from FWHA, 2010
Ultimate bond stress fs =
2.00 MPa
Reduction factor α = 0.22 From graph below
(Tomlinson, 1994)
Correction factor β = 0.72 From graph below
RQD = 60.0%
Therefore mass factor j = 0.32
(Tomlinson, 1994)
Rock socket shaft friction resistence fs =
= 0.22 x 0.72 x 2
= 0.317 MPa
Ultimate Friction Capacity per m FS = fs x Øπ
0.9 m = 0.3168 x 0.9 x π x 1000
= 895.7 kN/m
Ulitmate Socket Friction Capacity = FS x Ls
= 895.8 x 6.5
= 5822 kN
LRFD Geotechnical Resistance Factor = 0.55
for Sockets in Compression Apply to LRFD factored Load
FHWA - Table 10.5
Ultimate LRFD factored Load = 3003 x 1 / 0.55
= 5460 kN
® Criterium Ultimate Friction Capacity = 5460 / 5823
= 0.94 < 1 therefore OK
Design Calculations
αβquc
quc =
Reduction Factors for Rock Socket Skin
Friction
Reduction Factors for Discontinuities in
Rock Mass
αβquc
Ignore end bearing - DLP report (Mozal, 99) Stated that as the nature of the intermittent or alternating sequence of very weakly cemented sands and very soft rock sandstone will result in a high degree of uncertainty regarding the base resistance of these piles
- For Ø Ds =
(Use API LRFD factored ulimate loads from Prokon model)
Axial Compression Settlement
Pile head settlement will be caused by the compression of the rock socket only.
Settlement Settlement of pile head where load is only carried by rock socket skin friction
Settlement ρ =
Ip = 0.18 See below
L/B = 7.2
R = Ec/Ed
Ec = 20000 MPa
Deformation modulus Ed = Section 5.5 Tomlinson
Mr = 150 See below
= 150 x 0.32 x 2
= 96 MPa
R = 208
(Tomlinson, 1994)
(Tomlinson, 1994)
F = 0.82 See below
D/B = 3.3 Assume 3m pentration of casing
(D = recess)
Factor F
(Tomlinson, 1994)
® Criterium Pile Head Settlement ρ =
= 0.82 x 2238 x 0.18 / ( 0.9 x 96 )
= 3.8 mm
F x PDE(working) x Ip/(Ds x Ed)
Mr x j x quc
Elastic settlement influence factors for
rock sockets skin friction on piles
Values for Mr Section 5.5
Reduction factors for calculation of settlement of
recessed sockets
Socket assumed recessed - pile casing pentrates +- 3m into
rock
F x PDE(working) x Ip/(Ds x Ed)
The Ultimate Axial Tensile Capacity of The Substructure is The Lesser Value of the 'Pull out Resistance' and 'Axial Tension' Pull Out Resistence
Ultimate pull out resistance - Based on pull out cone
- Tomlinson 1994
- LRFD design factors from FWHA, 2010
Ultimate pull out resistance resistance weight rock pull out cone
Ignore weight contribution of soft silty clay overlaying rock
Vc = Volume rock cone
= 1/3(π)(Ls/2+Pd)((Ds/2)² + (Ds/2)(Ds/2+(LS/2+Pd)tan30)
+ (Ds/2+(LS/2+Pd)tan30)²)
= 1/3π(6.5/2+3)x((0.9/2)^2+((0.9/2)x(0.9/2)+(6.5/2+3)xTAN30))
+((6.5/2+3)xTAN30))^2))-(πx0.9/2x(6.5+3))
= 117.10
Vs = Volume socket
= π(Ds/2)(Ls)
= P x (0.9/2)^2 x (6.5)
= 4.14
= 117.11 x (20 - 10) + 4.14 x (25 - 10)
= 1233.07 kN
LRFD Geotechnical Resistance Factor = 1
for Sockets in Compression Apply to LRFD factored Load
FHWA - Table 10.5 - LRFD Resistance factor changed to 1 as a result of conservative
cone shape assumption - TomlinsonUltimate LRFD factored Load = 1 x 1 / 1
= 1 kN
® Criterium Ultimate Pull Out Resistance =
= 1 / 1234
= 0.00 < 1.0 therefore OK
Rpullout =
Assume a conservative half cone angle of 30˚ and bottom of pull out cone taken at the mid point of the bond length
Rpullout = Vc x γ'rock + Vs x γ'socket
m³
m³
Rpullout = Vc x γ'rock + Vs x γ'socket
(Use API LRFD factored ulimate loads from Prokon model)
Bonded length = Ls
Ls/2
Seabed - Soft silty clay
Rock level
Rock Socket
Penetration depth of casing = Pd
30˚
30˚
Ds
Axial Tension
Rock Socket Shaft Friction - ultimate bond stress between socket concrete and rock
- From Tomlinson - Equ: 4.25 Assumption that same calc as compression governs
- LRFD design factors from FWHA, 2010
Ultimate bond stress fs =
2.00 MPa
Reduction factor α = 0.22 From graph below
(Tomlinson, 1994)
Correction factor β = 0.72 From graph below
RQD = 60.0%
Therefore mass factor j = 0.32
(Tomlinson, 1994)
Rock socket shaft friction resistence fs =
= 0.22 x 0.72 x 2
= 0.317 MPa
Ultimate Friction Capacity per m FS = fs x Øπ
m = 0.3168 x 0.9 x π x 1000
= 895.7 kN/m
Ulitmate Socket Friction Capacity = FS x Ls
= 895.8 x 6.5
= 5822 kN
LRFD Geotechnical Resistance Factor = 0.45
for Sockets in Compression Apply to LRFD factored Load
FHWA - Table 10.5
Ultimate LRFD factored Load = 1 x 1 / 0.45
= 0 kN
® Criterium Ultimate Friction Capacity = 0 / 5823
= 0.00 < 1 therefore OK
αβquc
quc =
Reduction Factors for Rock Socket Skin
Friction
Reduction Factors for Discontinuities in
Rock Mass
αβquc
- For Ø Ds =
(Use API LRFD factored ulimate loads from Prokon model)
PRESTEDGE RETIEF DRESNER WIJNBERG (PTY) LTD
CONSULTING PORT AND COASTAL ENGINEERS
PROJECT 1096 Matola TCM - Phase 4 - FEL 3 DATE 4/7/2023 SHEET # 01 of 01
ISSUED BY SIGNED DATE SECTION Socket Sizing - Ø 1016 x 18wt Piles
DESIGN WGD DRAWING REF. 1096/00/5040 and 1096/00/5100
CHECKED SAH MODEL REF. NA
APPROVED PES CALC # 1096|Socket Ø 1016 Piles|001 Rev 00
CALC FILE REF. X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\WGD\4. Calculations
MODEL FILE REF.
CHECK 2. Design of rock socket for lateral loading - Based on Tomlinson and FHWA, 2010 using LPIle v 6.0 from Ensoft
Input Calculation Note
Tomlinson's
FHWA, 2010 - Drilled Shafts: Construction Procedures and LRFD Design Methods
LPIle v 6.0 Pile design software from Ensoft
Pile Reference Pile Group Ø 1016 x 18wt PilesCritical Pile D4 (Comp) & D3 (Lat)Position (in x) All 1016mm PilesRock Level -18.5 m MSL
Critical Load Combination 0Raked (Y/N) N
Outside Diameter D 1.016 m
Wall Thickness t 0.018 m
Level at top of pile z1 1.70 m MSL
Sea bed level z2 -18.50 m MSL
Raking angle a 0.24 RAD
Socket Length Ls 6.50 m
Socket outside diameter Ds 0.90 m
Penetration depth Pd 3.00 m
Section PropertiesInside Diameter d 0.98 m
Steel area AS 0.056
Total plug area AT 0.754
Moment of Inertia I 0.007
Elast. Sect. Mod. Ze 0.014
Plast. Sect. Mod. Zp 0.018
Radius of Gyration r 0.353 m
Elastic Modulus Steel Es 210000 MPa
Steel yield Strength Fy 350 MPa
Unit weight of steel g steel 77
Elastic Modulus Concrete Ec 20000 MPa
Concrete Strength fc 45 MPa
Unit weight of reinforced concrete γ concrete 25
Rock UCS 2.00 MPa
RQD RQD 60%
Unit weight of rock y rock 20.00
Loading
See load case table below
Design ChecksRock Socket Design Checks Criteria Reference Results Condition Status
Lateral Loading
Casing Factored Moment Resistance OK OK
Socket Factored Moment Resistance OK OK
Deflection at ULS 0.0036 OK
X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\DJP\2. Design\Prokon Models\Phase 4A - 4B loading\Final - incl. add. Rakers\1096 - 4A Berth 4B Loads - 2012-03-21 - API Rev01.A03
Calculation Description
Spreadsheet Notation
Governing Code Reference
Member Dimentions
m²
m²
m⁴
m³
m³
Material Properties
kN/m³
kN/m³
quc
kN/m³
ρ < 10% shaft Ø
PILE INTERACTION GRAPHS
Pile and Socket Sections Resisting Lateral Loading
Section 1:
Concrete shaft with permanent casing
Allows for variations in penetration of casing
Allows for damage to the rocks top layer's lateral resistance
as a result of installing the pile
(Design calls from 3m pentration)
Section 2:
Concrete shaft - Rock socket
Length to be confirmed
Unfactored Pile Interaction Bending Moments
Determined using LPIle v 6.0
Unfactored Moment ResistanceLoad Step Axial Load (kN) Socket (kNm) Casing (kNm)
1 -2000 860 8117
2 0 1444 8490
3 2000 1958 8817
4 4000 2347 9064
5 6000 2654 9260
6 8000 2863 9387
7 10000 2943 9443
Factored Pile Interaction Bending Moments
Ø = Structural Resistence factor 0.75 FHWA (2010) 16.7
Factored Moment ResistanceLoad Step Axial Load (kN) Socket (kNm) Casing (kNm)
1 -2000 645 6088
2 0 1083 6368
3 2000 1469 6613
4 4000 1760 6798
5 6000 1991 6945
6 8000 2147 7040
7 10000 2207 7082
Design Calculations
Assume only 2.25m of section length assists with lateral resistance
6000 6200 6400 6600 6800 7000 7200
-4000
-2000
0
2000
4000
6000
8000
10000
12000 Factored Casing Moment Resistance
Factored Bending Moment (kNm)
Fact
ored
Axi
al Lo
ad (k
N)
OD: 1016mmSide walls : 18mmRebar: 12No. Y32Conc: 45MpaCover: 174mm
Actual Rock Level
Assumed Rock level
Concrete shaft with permanent casing
Concrete shaft - rock socket
6000 6200 6400 6600 6800 7000 7200
-4000
-2000
0
2000
4000
6000
8000
10000
12000 Factored Casing Moment Resistance
Factored Bending Moment (kNm)
Fact
ored
Axi
al Lo
ad (k
N)
LPILE - SOIL MODEL PILE CAPACITY CHECKS
Load Cases for Lpile Inputs: Load cases taken from various representative combination reaction outputs
from Prokon berth model
Need to add moment from pile alignment tolerances to Prokon moment to give total moment (tolerance +0.2m)
Load Case ULS Axial Load SLS Axial Load
(kN) (kN)
1 1897 3002.18 2497.38 2237.68
2 1391.05 464.61 1483.97 536.44
3 2401.11 1658.16 2732.74 1260.62
4 2457.84 2076.47 2873.13 1134.85
5 1817.72 1818.47 2181.42 981.93
LRFD Factored Load Cases for Lpile Inputs:
Ø = Geotechnical Lateral Resistence factor 0.67 FHWA (2010) 16.7
(p-y method push over analysis) - Lpile has used p-y method for weak rock to determine soil reaction
Load CaseSLS Axial Load
(kNm) (kN)
1 3727.43 2237.68
2 2214.88 536.44
3 4078.72 1260.62
4 4288.25 1134.85
5 3255.85 981.93
ULS Prokon Moment (kNm)
ULS Total Moment (kNm) (all pos+)
Total ULS Moment Factored by
Geotechnial Lateral Resistance Factos
400 600 800 1000 1200 1400 1600 1800 2000 2200 2400
-4000
-2000
0
2000
4000
6000
8000
10000
12000
Factored Socket Moment Resistance
Factored Bending Moment (kNm)
Fact
ored
Axi
al Lo
ad (k
N)OD: 900mmRebar: 12No. Y32Conc: 45MpaCover: 114mm
Bending Moment Vs Depth
Output from Lpile soil model.
Factored Pile Interaction Checks
Concrete Filled Casing Concrete Socket
(take results from model output) (take results from model output)
Load CaseMoment Axial Load Moment Axial Load
(kNm) (kN) (kNm) (kN)
1 3727 2238 820 2238
2 2215 536 245 536
3 4079 1261 910 1261
4 4288 1135 590 1135
5 3256 982 970 982
Socket Response
CasingResponse
Load cases are all within the factored concrete filled casing interaction curve
OK - Manual Check
Load cases are all within the factored concrete socket interaction curve
OK - Manual Check
1000 2000 3000 4000 5000 6000 7000 8000
-4000
-2000
0
2000
4000
6000
8000
10000
12000Factored Casing Moment Resistance
Factored Bending Moment (kNm)
Fact
ored
Axi
al Lo
ad (k
N)
0 500 1000 1500 2000 2500
-4000
-2000
0
2000
4000
6000
8000
10000
12000Factored Socket Moment Resistance
Factored Bending Moment (kNm)
Fact
ored
Axi
al Lo
ad (k
N)
LPILE - SOIL MODEL DEFLECTIONS
ULS delfections
Deflection Vs Depth
Maximum Deflection = 0.0036 m From Chart
10% of shaft dia. = 0.09 m OK
FHWA, 2010 - 12.3.3.3.1
Length Check
Is socket long enough for lateral loads
OK - Manual Check
X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\DJP\2. Design\Prokon Models\Phase 4A - 4B loading\Final - incl. add. Rakers\1096 - 4A Berth 4B Loads - 2012-03-21 - API Rev01.A03 ULS
AXIAL FORCE X MOMENT Z MOMENT
MAXIMUM MINIMUM MAXIMUM MINIMUM MAXIMUM MINIMUM
Node Max Axial LC X-Moment Z-Moment Node Min Axial LC Max X-Moment Max Z-Moment Node Max X Moment LC Max Axial Max Z-Moment Node Min X Moment LC Max Axial Max Z-Moment Node Max Z Moment LC Max Axial Max X-Moment Node Min Z Moment LC Max Axial Max X-Moment
[kN] [kNm] [kNm] [kN] [kNm] [kNm] [kNm] [kN] [kNm] [kNm] [kN] [kNm] [kNm] [kN] [kNm] [kNm] [kN] [kNm]
10899 3002.18 B1LT+ 1415.65 -1262.67 11894 464.61 M11UT- -466.91 1310.35 11894 2109.22 B1LT+ 1658.16 -1147.39 10896 -1647.36 M1ET- 2509.13 1824.05 10898 1852.80 M1ET- 2076.47 -1558.06 10896 -1610.40 B1WMT+ 1818.47 843.05
9954 1733.16 B21LT- 579.61 -434.50 733.73 M11UT+ 83.43 324.64 579.61 B21LT- 1733.16 -434.50 -35.53 M17DT+ 1526.14 359.56 365.25 M1ET+ 1086.76 97.10 -488.18 B21WT- 1673.60 506.91
9951 1165.47 B21LT- 417.59 -398.73 743.32 M11UT+ 86.28 290.93 417.59 B21LT- 1165.47 -398.73 -83.68 M17DT+ 1054.83 353.97 353.97 M17DT+ 1054.83 -83.68 -435.91 B21WT- 1155.49 344.67
9948 1136.78 B21LT- 343.12 -403.00 725.56 M11UT+ 71.95 306.32 343.12 B21LT- 1136.78 -403.00 -59.73 M17DT+ 1044.49 370.04 370.04 M17DT+ 1044.49 -59.73 -449.38 B21WT- 1133.79 295.37
9945 1141.68 STLW 228.44 -13.39 731.53 M11UT+ 61.27 263.37 270.33 B21LT- 1137.24 -354.44 40.97 M17DT+ 1062.92 332.68 333.05 M1ET+ 1098.41 147.77 -399.46 B21WT- 1136.31 254.21
9942 1126.93 STLW 188.58 -10.67 722.25 M11UT+ 26.39 237.66 251.40 B11LT+ 1102.80 237.40 -27.85 M11S1- 736.81 -252.09 308.02 M1ET+ 1088.02 143.54 -356.53 B21WT- 1120.74 193.64
9939 1134.39 STLW 222.46 -11.47 716.67 M11UT+ -18.68 206.52 337.66 B11LT+ 1121.94 234.36 -128.78 M11S1- 717.40 -249.44 293.22 M1ET+ 1098.36 186.40 -331.32 B21WT- 1119.52 191.91
9936 1129.55 B11LT- 375.18 -147.46 700.66 M11S1- -291.76 -222.10 457.44 B11LT+ 1122.02 237.42 -291.76 M11S1- 700.66 -222.10 265.03 M1ET+ 1087.95 184.14 -292.47 B21WT- 1107.44 150.71
9933 1183.43 B11DT+ 710.16 212.89 681.21 M11S1- -394.14 -155.67 710.25 B11LT+ 1183.40 212.71 -394.14 M11S1- 681.21 -155.67 228.77 M1ET+ 1103.62 219.10 -245.31 B21WT- 1113.18 162.65
9930 1165.75 B11DT+ 872.79 128.03 668.24 M11S1- -531.41 -116.53 872.79 B11DT+ 1165.75 128.03 -531.41 M11S1- 668.24 -116.53 231.29 M1ET+ 1081.94 226.53 -240.86 B21WT- 1090.54 127.54
9927 1780.21 B11DT+ 940.53 1.36 688.02 M11UT- -251.50 -67.45 940.56 B11LT+ 1780.18 1.14 -384.16 M11S1- 1153.77 -39.24 187.69 M1ET+ 1095.87 253.97 -201.83 B11LT- 1768.22 771.88
9924 1126.80 B11LT+ 554.54 -30.61 677.23 M11S1- -381.30 40.86 554.54 B11LT+ 1126.80 -30.61 -381.30 M11S1- 677.23 40.86 170.59 M11ST+ 1024.06 -131.13 -158.77 B11LT- 1113.30 365.21
9921 1116.76 STLW 299.03 -3.13 677.55 M11S1- -254.11 60.91 477.97 B11LT+ 1116.08 -23.72 -254.11 M11S1- 677.55 60.91 133.46 M1ET+ 1083.28 272.23 -116.67 B21WT- 1079.92 138.08
9918 1114.69 B5LT+ 550.96 -18.99 688.08 M11S1- -167.60 70.84 550.96 B5LT+ 1114.69 -18.99 -176.09 M1DT- 1008.74 -2.56 124.46 M1ET- 1045.29 -32.88 -101.39 B21WT+ 1092.37 360.30
9915 1143.55 B5LT+ 679.86 -37.13 695.69 M11UT- -98.25 97.19 679.86 B5LT+ 1143.55 -37.13 -378.96 M1DT- 983.15 29.78 158.27 M1ET- 1054.23 -24.16 -135.71 B21WT+ 1096.03 361.40
9912 1139.81 B5LT+ 818.49 -142.84 693.84 M11UT- -89.85 147.08 818.49 B5LT+ 1139.81 -142.84 -444.62 M1DT- 977.81 158.71 218.34 M1ET- 1036.79 -125.30 -171.81 B21WT+ 1072.89 331.65
10899 3002.18 B1LT+ 1415.65 -1262.67 1569.10 M11UT- -686.80 1323.28 1415.65 B1LT+ 3002.18 -1262.67 -1446.49 M1ST- 2296.80 1503.09 1582.84 M1ET- 2316.92 -1373.46 -1603.42 B1WMT+ 2816.91 1034.27
10898 2076.70 M1ST- -1571.43 1770.92 1340.92 B11UT+ 454.44 -1338.42 1176.04 B1LT+ 1851.29 -1213.05 -1571.43 M1ST- 2076.70 1770.92 1852.80 M1ET- 2076.47 -1558.06 -1559.17 B1WMT+ 1896.09 811.65
10896 2509.13 M1ET- -1647.36 1824.05 1273.99 B11UT+ 471.39 -1388.01 1231.84 B1LT+ 1776.53 -1259.01 -1647.36 M1ET- 2509.13 1824.05 1824.05 M1ET- 2509.13 -1647.36 -1610.40 B1WMT+ 1818.47 843.05
10894 1570.29 B1WMT+ 965.20 -1587.40 645.49 M11S1- -745.30 1336.74 1345.66 B1LT+ 1152.40 -1299.80 -1585.62 M1ET- 1066.80 1607.08 1607.08 M1ET- 1066.80 -1585.62 -1604.16 B3WT+ 1273.87 925.78
11903 1138.41 B1LT+ 1459.88 -690.01 602.24 M11UT- -488.20 1266.53 1459.88 B1LT+ 1138.41 -690.01 -1034.24 M1DT- 698.63 1403.22 1558.44 M1ET- 764.61 -868.00 -1130.08 B5LT+ 1003.12 1157.34
11901 2032.70 B1LT+ 1493.67 -889.74 969.35 M11UT- -439.50 1336.50 1493.67 B1LT+ 2032.70 -889.74 -961.98 M1ST- 1356.55 1606.53 1610.42 M1ET- 1380.78 -871.71 -1345.52 B5LT+ 1965.52 1028.77
11898 2554.23 B1LT+ 1908.64 -1052.88 1555.36 M11UT- -426.74 1400.65 1908.64 B1LT+ 2554.23 -1052.88 -943.35 M1ST- 2159.95 1664.78 1668.73 M1ET- 2164.11 -931.13 -1505.22 B5LT+ 2413.71 1210.81
11896 2352.28 B1LT+ 2083.38 -1066.61 1453.27 B11UT- -326.65 1166.42 2083.38 B1LT+ 2352.28 -1066.61 -923.33 M1ET- 2022.66 1721.09 1721.09 M1ET- 2022.66 -923.33 -1525.39 B5LT+ 2184.85 1262.61
11894 1658.38 B3WT+ 1699.96 -1488.64 464.61 M11UT- -466.91 1310.35 2109.22 B1LT+ 1658.16 -1147.39 -1034.27 M1ET- 675.14 1534.46 1534.46 M1ET- 675.14 -1034.27 -1565.82 B5LT+ 1590.22 1192.63
X:\PRDW Projects\Current\Mozambique (1096) Matola TCM FEL 3\Working\Engineers\DJP\2. Design\Prokon Models\Phase 4A - 4B loading\Final - incl. add. Rakers\1096 - 4A Berth 4B Loads - 2012-03-21 - API Rev01.A03 SLS
AXIAL FORCE X MOMENT Z MOMENT
MAXIMUM MINIMUM MAXIMUM MINIMUM MAXIMUM MINIMUM
Node Max Axial LC X-Moment Z-Moment Node Min Axial LC Max X-Moment Max Z-Moment Node Max X Moment LC Max Axial Max Z-Moment Node Min X Moment LC Max Axial Max Z-Moment Node Max Z Moment LC Max Axial Max X-Moment Node Min Z Moment LC Max Axial Max X-Moment
[kN] [kNm] [kNm] [kN] [kNm] [kNm] [kNm] [kN] [kNm] [kNm] [kN] [kNm] [kNm] [kN] [kNm] [kNm] [kN] [kNm]
10899 2237.68 B1LT+ 989.30 -968.43 11894 536.44 M1ET- -720.08 1134.85 11894 1524.21 B1LT+ 1260.62 -890.91 10896 -1192.40 M1ET- 1912.43 1350.87 10898 1371.82 M1ET- 1592.09 -1124.83 10894 -1205.76 B3WT+ 981.93 656.68
9954 1268.92 B21LT- 408.67 -323.17 819.89 M1ST+ 91.05 267.04 408.67 B21LT- 1268.92 -323.17 -8.97 M17DT+ 1126.06 274.07 277.57 M1ET+ 836.85 79.48 -358.95 B21WT- 1229.22 360.20
9951 893.72 B21LT- 303.15 -296.37 813.74 M17DT+ -39.56 266.47 303.15 B21LT- 893.72 -296.37 -39.56 M17DT+ 813.74 266.47 266.47 M17DT+ 813.74 -39.56 -321.16 B21WT- 887.06 254.54
9948 872.94 B21LT- 252.61 -300.50 804.61 M17DT+ -23.14 278.93 252.61 B21LT- 872.94 -300.50 -23.14 M17DT+ 804.61 278.93 278.93 M17DT+ 804.61 -23.14 -331.42 B21WT- 870.95 220.78
9945 879.92 STLW 178.21 -9.83 818.26 M17DT+ 45.25 250.21 203.46 B21LT- 874.01 -264.75 45.25 M17DT+ 818.26 250.21 250.21 M17DT+ 818.26 45.25 -294.77 B21WT- 873.40 192.71
9942 868.43 STLW 147.02 -7.79 813.82 M11ST+ 47.91 184.59 187.66 B11LT+ 847.61 183.45 37.68 M11ST- 1657.30 -384.96 230.52 M1ET+ 837.75 115.76 -262.79 B21WT- 861.54 147.79
9939 874.38 STLW 174.12 -8.38 809.20 M11ST+ 10.40 156.20 249.10 B11LT+ 861.45 179.24 -27.17 M11ST- 1633.15 -377.22 218.48 M1ET+ 845.73 148.25 -243.86 B21WT- 860.81 146.91
9936 867.38 B11UT- 275.91 -117.16 795.74 M11ST+ -79.26 129.61 328.36 B11LT+ 860.35 178.25 -142.54 M11ST- 1603.59 -332.90 196.66 M1ET+ 837.65 146.17 -214.48 B21WT- 851.42 115.44
9933 903.53 B11UT- 432.17 -80.65 791.43 M11ST- -415.04 -236.88 499.94 B11LT+ 902.82 157.95 -207.52 M11ST- 1582.85 -236.88 168.66 M1ET+ 849.68 172.51 -179.29 B21WT- 855.96 124.37
9930 888.88 B11DT+ 609.97 100.37 775.64 M11ST- -608.08 -180.48 609.97 B11DT+ 888.88 100.37 -304.04 M11ST- 1551.28 -180.48 169.21 M1ET+ 833.12 179.13 -174.78 B21WT- 838.39 96.96
9927 1300.07 B11DT+ 657.98 11.57 791.63 M11UT- -114.41 -52.67 658.00 B11LT+ 1300.05 11.43 -201.58 M11ST- 2204.75 -70.12 135.80 M1ET+ 843.87 200.28 -145.14 B11UT- 1292.70 540.80
9924 863.40 B11LT+ 399.68 -13.31 781.34 M11ST- -408.88 46.28 399.68 B11LT+ 863.40 -13.31 -204.44 M11ST- 1562.68 46.28 121.72 M11ST+ 791.15 -58.80 -112.52 B11UT- 854.46 265.84
9921 860.36 STLW 229.98 -2.66 780.48 M11ST- -225.24 80.18 372.67 B11UT+ 859.00 -3.24 -112.62 M11ST- 1560.96 80.18 92.44 M1ET+ 834.75 218.19 -80.23 B21WT- 830.30 104.44
9918 854.67 B5LT+ 402.36 -13.88 777.82 M1DT- -109.66 0.94 402.36 B5LT+ 854.67 -13.88 -109.66 M1DT- 777.82 0.94 84.68 M1ET- 805.98 -12.41 -68.81 B21WT+ 839.80 275.26
9915 874.47 B5LT+ 488.70 -30.62 761.04 M1DT- -244.93 26.88 488.70 B5LT+ 874.47 -30.62 -244.93 M1DT- 761.04 26.88 111.54 M1ET- 812.63 -4.35 -96.34 B21WT+ 842.83 276.39
9912 869.85 B5LT+ 578.41 -104.98 755.92 M1DT- -288.43 118.16 578.41 B5LT+ 869.85 -104.98 -288.43 M1DT- 755.92 118.16 156.92 M1ET- 799.03 -74.81 -124.29 B21WT+ 825.33 253.85
10899 2237.68 B1LT+ 989.30 -968.43 1732.86 M11UT- -584.13 1010.23 989.30 B1LT+ 2237.68 -968.43 -1032.11 M1ST- 1765.14 1122.56 1172.27 M1ET- 1778.08 -976.22 -1195.60 B1WMT+ 2114.27 735.05
10898 1592.99 M1ST- -1139.86 1320.99 1434.14 B1LT+ 811.16 -933.83 811.16 B1LT+ 1434.14 -933.83 -1139.86 M1ST- 1592.99 1320.99 1371.82 M1ET- 1592.09 -1124.83 -1164.57 B1WMT+ 1464.13 568.24
10896 1912.43 M1ET- -1192.40 1350.87 1383.82 B1LT+ 850.70 -971.04 850.70 B1LT+ 1383.82 -971.04 -1192.40 M1ET- 1912.43 1350.87 1350.87 M1ET- 1912.43 -1192.40 -1205.30 B1WMT+ 1411.93 591.51
10894 1179.62 B1WMT+ 682.96 -1194.59 685.74 B1LT- -23.65 897.32 936.60 B1LT+ 900.58 -1002.85 -1145.62 M1ET- 816.22 1188.42 1188.42 M1ET- 816.22 -1145.62 -1205.76 B3WT+ 981.93 656.68
11903 855.63 B1LT+ 1044.88 -540.95 554.89 M1DT- -724.39 1054.15 1044.88 B1LT+ 855.63 -540.95 -724.39 M1DT- 554.89 1054.15 1154.53 M1ST- 569.52 -717.43 -834.34 B5LT+ 765.47 843.19
11901 1548.37 B1LT+ 1066.47 -694.49 1059.28 M1ST- -673.93 1193.20 1066.47 B1LT+ 1548.37 -694.49 -673.93 M1ST- 1059.28 1193.20 1193.20 M1ST- 1059.28 -673.93 -998.34 B5LT+ 1503.68 756.53
11898 1949.01 B1LT+ 1375.70 -819.43 1672.11 M1ST- -657.93 1236.62 1375.70 B1LT+ 1949.01 -819.43 -657.93 M1ST- 1672.11 1236.62 1236.62 M1ST- 1672.11 -657.93 -1120.99 B5LT+ 1855.44 910.48
11896 1791.72 B1LT+ 1506.07 -830.37 1564.73 M1ET- -635.63 1275.50 1506.07 B1LT+ 1791.72 -830.37 -635.63 M1ET- 1564.73 1275.50 1276.18 M1ST- 1568.19 -616.76 -1136.23 B5LT+ 1680.23 958.89
11894 1260.94 B3WT+ 1251.37 -1118.41 536.44 M1ET- -720.08 1134.85 1524.21 B1LT+ 1260.62 -890.91 -720.08 M1ET- 536.44 1134.85 1135.49 M1ST- 543.47 -668.88 -1169.86 B5LT+ 1215.53 913.15
CONFORMING ROCK SOCKET DESIGN TO EUROCODE 7
Base on Geotechnical Laboratory and Site Investigation.ULTIMATE LIMIT STATE
The ultimate bearing capacity for rock sockets are only dependant on skin friction. Therefore the the fundamental Equation is:
The above equation is based on the following site specific soil/rock properties that need to be measured:*Rock Quality Designation*Rock Unconfined Compressive Strength*Mass factor
**α is determine from the graph below utilizing the field test result for the quc
Based on the number of test results collected for the above material properties, their respective skin friction can be determined
Rs1 = Fs 1 * Contact AreaRs2 = Fs 2 * Contact Area…
Then the determine the charateristic resistance (Rsk) using the appropriate correlcation factors according to number of tests completed
**β is determine from the graph below utilizing the field test result for the Mass factor (j) based on the elastic modulus of the rock
Design Approach 1: Combination 1(Design Resistance set by partial factor set R1 according to piling type)
(Design Actions set by partial factor set A1)
Design Action (Fd) = G*1.35 + Q*1.5
R 1 R4 with explicit verification R4 without explicit verificationDriven Bored CFA Driven Bored CFA Driven
1 1 1 1.5 1.7 1.7 1.7Shaft com, ϒs 1 1 1 1.3 1.4 1.4 1.5Shaft ten, ϒs,t 1 1 1 1.5 1.7 1.7 1.7Total, ϒt 1 1 1 1.7 1.7 1.7 2
SERVICEABILITY LIMIT STATE
Design Resistance (Rd) = Rsk/ϒs
Overal Design Safety Factor (Г) = Rd/Fd
Base, ϒb
Hence the allowable pile settlement is set by the engineer and is project specific, settlements are generally limited between 10mm to 25mm at pile head
Example: (same as in spreadsheet)
The settlement (ρ) for piles with rock sockets can be determined from the following equation established by Pells and Turner
F is a reduction factor to account for the pile
recess
Standard calculation method
RQD (assumed) % 602
Therefore, based on equation 1 Fs = 895.7 MpaUltimate bearing capacity Qu = 5822kN
0.94
EC 7 calculation method
Rs;k = 5822/1.55 3756.129 kN
Design Combination 1 Design Combination 2Rd = Rs,k/1.0 3756 Rd = Rs,k/1.6Fd = 3003 Fd =
0.799521
Refer to example 4.7 of tomlinson's; a rock socket design in weak mudstone has been undertaken. Tomlinsons assumes that both shaft friction and base bearing are activated.He utilizes a factor of safety of 3 for the Ultimate bearing resistance Qu. Shaft resistance is more than twice the working load and end bearing is 0.9 times the working load
quc MN/m² (assumed)
Overal Design Factor (Г) = Rd/Fd
Overal Design Factor (Г) = Rd/Fd Overal Design Factor (Г) = Rd/Fd
CONFORMING ROCK SOCKET DESIGN TO EUROCODE 7
Base on Geotechnical Laboratory and Site Investigation.
The ultimate bearing capacity for rock sockets are only dependant on skin friction. Therefore the the fundamental Equation is:
eqn 1
The above equation is based on the following site specific soil/rock properties that need to be measured:
Based on the number of test results collected for the above material properties, their respective skin friction can be determined
Then the determine the charateristic resistance (Rsk) using the appropriate correlcation factors according to number of tests completed
is determine from the graph below utilizing the field test result for the Mass factor (j) based on the elastic modulus of the rock
Design Approach 1: Combination 2(Design Resistance set by partial factor set R4 according to piling type)
(Design Actions set by partial factor set A2)
Design Action (Fd) = G*1.0 + Q*1.3
R4 without explicit verificationBored CFA
2 21.6 1.62 22 2
Design Resistance (Rd) = Rsk/ϒs
Overal Design Safety Factor (Г) = Rd/Fd
Hence the allowable pile settlement is set by the engineer and is project specific, settlements are generally limited between 10mm to 25mm at pile head
for piles with rock sockets can be determined from the following equation established by Pells and Turner
Design Combination 22347.5
2238
0.953355
Refer to example 4.7 of tomlinson's; a rock socket design in weak mudstone has been undertaken. Tomlinsons assumes that both shaft friction and base bearing are activated.He utilizes a factor of safety of 3 for the Ultimate bearing resistance Qu. Shaft resistance is more than twice the working load and end bearing is 0.9 times the working load
Overal Design Factor (Г) = Rd/Fd
CONFORMING ROCK SOCKET DESIGN TO EUROCODE 7
Design Approach 1: Combination 2(Design Resistance set by partial factor set R4 according to piling type)