Sheet Pile Structures
Depending on the way the retaining structure is built and analyzed, it can be divided into three categories: 1. Cantilever Sheet Pile 2. Anchored Sheet Pile 3. Braced Sheet Pile Cantilever Sheet Pile
Case 1 (Sheet Pile Penetrating Sandy Soils)
A few key points that define the lateral earth pressure in Figure 8.7: 1. Point A to Point D (p1): Active earth pressure on the right hand side. 2. Point D to Point H (p3): (Passive earth pressure on the left hand side) - (Active
earth pressure on the right hand side). 3. Point G (p4): (Passive earth pressure on the right hand side) - (Active earth
pressure on the left hand side). 4. Point E (L3): Can be determined from equation derived in 2. 5. Point F (L5): To be determined. Unknowns: D and L5
Equations: 0=∑ xF
0=∑ BM
The actual depth of penetration is increased by 20%~30% for construction. To calculate maximum bending moment: 1. Determine point of zero shear force: let P (area of ACDE) = Shaded area E-F” 2. Moment can be determined at the section of zero shear force.
Case 2 (Sheet Pile Penetrating Clay)
A few key points that define the lateral earth pressure in Figure 8.7: 1. Point A to Point D (p1): Active earth pressure on the right hand side. 2. Point F to Point I (p6): (Passive earth pressure on the left hand side) - (Active earth
pressure on the right hand side). 3. Point G (p7) : (Passive earth pressure on the right hand side) - (Active earth
pressure on the left hand side). 4. Point E (L3): Can be determined from equation derived in 2. 5. Point G (L4): To be determined Unknowns: D and L4
Equations: 0=∑ xF
0=∑ BM
To calculate maximum bending moment: 1. Determine point of zero shear force 2. Moment can be determined at the section of zero shear force.
Anchored Sheet Pile The two basic methods of designing anchored sheet pile walls are (a) the free earth support method and (b) the fixed earth support method.
Dfree earth < Dfixed earth
Case 1. (Free earth support method for penetration of sandy soil)
Unknowns: D and T
Equations: 0=∑ xF
0=∑ oM
The actual depth of penetration is increased by 30%~40% for construction.
Anchors
Ultimate Resistance of Tiebacks
In Sand:
φσπ tan' KdlP vu =
K = K0 if the concrete grout is placed under pressure Lower limit of K is Rankine Ka In Clay:
au dlcP π=
ca = adhesion ≈ uc32
Factor of Safety = 1.5-2.0 may be used over ultimate resistance to obtain the allowable resistance offered by each tieback.
Braced Cut ♦ To avoid considerable settlement or bearing capacity failure of nearby structure. ♦ To prevent water seepage into excavation Pressure Envelop for Braced Cut Design The struts limit lateral wall movement, Ka not mobilized, P > Pa by 10% ~15%. After observation of several braced cuts, Peck (1969) suggested using design pressure envelops (apparent pressure envelop) γh/cu > 4 γh/cu < 4
≥ 0.3 γH
Limitations: 1. Pa may depend on construction sequence. 2. They apply when H ≥ about 6 m. 3. G.W.T. below the bottom of excavation 4. Sand is drained (uw =0) 5. Clay is undrained (uw not considered) Cuts in Layered Soil
Case (a)
⎟⎠⎞
⎜⎝⎛ += ucssssav CnHHK
HC 'tan
211 2 φγ
Ks = K for sand layer (≈ 1) n' = a coefficient of progressive failure, 0.5 ~1.0, average 0.75. Case (b)
( )K++= 22111 HCHCH
Cav
( )K++= 22111 HHHav γγγ
Braced Cut Design
Strut The strut force can be determined from (b) above. Sheet Pile Maximum moment on sheet pile can be determined from (b) above. Wales Treated as continuous horizontal members if they are spliced properly. Or conservatively treated as though they are pinned at the struts.
At level A 8
))(( 2
maxsAM =
At level B 8
))(( 221
maxsBBM +
=
At level C 8
))(( 221
maxsCCM +
=
At level D 8
))(( 2
maxsDM =
Stability of Open Cut Bottom Heaving of a Cut in Clay
2.17.5
1
1 ≥−
=HCHB
BCFS
u
u
γ
5.1'"2.0114.5
≥+
+⎟⎠⎞
⎜⎝⎛ +
=qH
BHC
LBC
FS
uu
γ
B’ = T if T ≤ B/ 2 ; B’ = B/ 2 if T > B/ 2 ; B” = 2 B’
Chang (2000)
Terzaghi (1943)
Piping of a Cut in Sand
5.1)max(
≥=exit
cr
ii
FS
Uplifting of a Cut in Inter-Layer
2.1)( 1
1 ≥Δ+
=ww
sat
HHH
FSγ
γ
Depth of Penetration
5.1≥−
=saa
pp
MlPlP
FS
H1
Uf = H1+ΔHw
Impervious
lp Pp Pa
la
Global Stability of Anchored Sheet Pile
5.1≥=o
r
MM
FS