Chöông 5 AÙp löïc ñaát – TÖÔØNG CHAÉN. Earth Pressures on Retaining walls Rankine’s Method.

Chöông 5 AÙp löïc ñaát – TÖÔØNG CHAÉN

Earth Pressures on Retaining walls Rankine’s Method

Modes of failure F

The force F may be provided by friction at the base (gravity retaining walls) F

Modes of failure The force F may be provided by friction at the base (gravity retaining walls) founding the wall into the ground (sheet retaining walls) F

Modes of failure The force F may be provided by friction at the base (gravity retaining walls) founding the wall into the ground (sheet retaining walls) anchors and struts F

Modes of failure The force F may be provided by friction at the base (gravity retaining walls) founding the wall into the ground (sheet retaining walls) anchors and struts external loads F

Modes of failure 1. ACTIVE Failure If the force F is too small failure of the wall will occur with soil pushing the wall out. F direction of soil movement

Modes of failure 1. ACTIVE Failure If the force F is too small failure of the wall will occur with soil pushing the wall out. F direction of soil movement For most retaining walls active failure is the primary concern.

Modes of failure 1. PASSIVE Failure If the force F is too large failure of the wall will occur with the wall pushing into the soil. F direction of soil movement

Modes of failure 1. PASSIVE Failure If the force F is too large failure of the wall will occur with the wall pushing into the soil. F direction of soil movement This mode of failure is usually only relevant when large external forces are being applied.

Modes of failure 1. PASSIVE Failure If the force F is too large failure of the wall will occur with the wall pushing into the soil. F direction of soil movement This mode of failure is usually only relevant when large external forces are being applied. However, local passive conditions may occur if any part of the wall moves towards the soil.

Assume that the wall is frictionless The normal stress acting on the wall will thus be a principal stress If the wall is vertical and the soil surface horizontal the vertical and horizontal stresses throughout the retained soil mass will be the principal stresses The vertical stress may then be calculated in the usual way Rankine’s theory

Assume that the wall is frictionless The normal stress acting on the wall will thus be a principal stress If the wall is vertical and the soil surface horizontal the vertical and horizontal stresses throughout the retained soil mass will be the principal stresses The vertical stress may then be calculated in the usual way Rankine’s theory d1d1 d2d2   z The vertical total stress at depth z is given by

Assume that the horizontal stress can be calculated from the failure criterion. That is the retained soil is assumed to be everywhere at failure. Rankine’s theory

Assume that the horizontal stress can be calculated from the failure criterion. That is the retained soil is assumed to be everywhere at failure. From the Mohr-Coulomb failure criterion we have Rankine’s theory

Assume that the horizontal stress can be calculated from the failure criterion. That is the retained soil is assumed to be everywhere at failure. From the Mohr-Coulomb failure criterion we have For active failure the horizontal stress will reduce to its minimum value. That is  h =   the minimum principal stress, and  v =  . Rankine’s theory

Assume that the horizontal stress can be calculated from the failure criterion. That is the retained soil is assumed to be everywhere at failure. From the Mohr-Coulomb failure criterion we have For active failure the horizontal stress will reduce to its minimum value. That is  h =   the minimum principal stress, and  v =  . The minimum (Active) horizontal stress is then Rankine’s theory

For passive failure the horizontal stress will increase to its maximum value. That is  h =   the maximum principal stress, and  v =  . Rankine’s theory

For passive failure the horizontal stress will increase to its maximum value. That is  h =   the maximum principal stress, and  v =  . The maximum (Passive) horizontal stress is then Rankine’s theory

For passive failure the horizontal stress will increase to its maximum value. That is  h =   the maximum principal stress, and  v =  . The maximum (Passive) horizontal stress is then If the vertical stress stays constant the horizontal stress is bounded by the active and passive values. Rankine’s theory

For passive failure the horizontal stress will increase to its maximum value. That is  h =   the maximum principal stress, and  v =  . The maximum (Passive) horizontal stress is then If the vertical stress stays constant the horizontal stress is bounded by the active and passive values. In the Rankine method a stress state is found that is in equilibrium with the applied loads and has the soil at failure. In plasticity theory this approach is referred to as a lower bound method, a method which can be shown to produce safe, conservative solutions. Rankine’s theory

The relation between the active and passive pressures may be shown graphically by considering Mohr circles.    c  tan  vv hh

Rankine’s theory The relation between the active and passive pressures may be shown graphically by considering Mohr circles.    c  tan  vv  hmin

Rankine’s theory The relation between the active and passive pressures may be shown graphically by considering Mohr circles.    c  tan  vv  hmin  hmax

Total Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of total stress, using undrained parameters c u,  u.

Total Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of total stress, using undrained parameters c u,  u. A total stress analysis is only appropriate if soil remains undrained. It can only be used in the short term for soils with low permeabilities.

Total Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of total stress, using undrained parameters c u,  u. A total stress analysis is only appropriate if soil remains undrained. It can only be used in the short term for soils with low permeabilities. For the undrained active failure of a wall we have

Total Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of total stress, using undrained parameters c u,  u. A total stress analysis is only appropriate if soil remains undrained. It can only be used in the short term for soils with low permeabilities. For the undrained active failure of a wall we have and for a homogeneous soil layer  v =  sat z where

H z c u,  u  sat Total Horizontal Stress

H z c u,  u  sat Total Horizontal Stress If  u is non-zero this implies that the undrained strength varies with depth. The soil must be saturated to use a total stress (undrained) analysis.

The analysis indicates negative, tensile, stresses at the surface. Soil particles cannot provide tension The negative stresses have to come from suctions in the pore water It is difficult to rely on the tensile forces and they are usually ignored The tensile stresses reduce the force required for stability of the wall. Ignoring the tensile stresses therefore gives a more conservative solution. Tension cracks

H z c u,  u  sat The horizontal stress distribution becomes z0z0

Tension cracks H z c u,  u  sat The horizontal stress distribution becomes z0z0 The depth of the tensile region z 0 may be determined from  h = 0

Tension cracks In the tensile region a crack can develop.

Tension cracks In the tensile region a crack can develop. If water is available it can fill the crack, and reduce the stability of the wall. The horizontal stresses on the wall become.

Tension cracks In the tensile region a crack can develop. If water is available it can fill the crack, and reduce the stability of the wall. The horizontal stresses on the wall become. z0z0  w z 0 Water Soil

Effective Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of effective stress, using effective parameters c’,  ’.

Effective Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of effective stress, using effective parameters c’,  ’. An effective stress analysis is always appropriate, irrespective of the drainage conditions. To perform an effective stress analysis the pore water pressures must be known. This usually limits effective stress analysis to investigation of long term stability.

Effective Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of effective stress, using effective parameters c’,  ’. An effective stress analysis is always appropriate, irrespective of the drainage conditions. To perform an effective stress analysis the pore water pressures must be known. This usually limits effective stress analysis to investigation of long term stability. For active failure of a wall we have

Effective Stress Analysis The Mohr-Coulomb failure criterion must be expressed in terms of effective stress, using effective parameters c’,  ’. An effective stress analysis is always appropriate, irrespective of the drainage conditions. To perform an effective stress analysis the pore water pressures must be known. This usually limits effective stress analysis to investigation of long term stability. For active failure of a wall we have and  ’ v =  v - u where

H z c’,  ’  dry Effective Stress Analysis Consider active failure of a wall retaining dry sand

The use of values of c’,  ’ associated with peak failure leads to the prediction of impossible tensile stresses. It is generally more appropriate and safer to use ultimate or critical state parameters, c’ = 0,  ’ =  ’ ult Using the critical state parameters a larger active force is required for wall stability, and hence a safer estimate is obtained Effective Stress Analysis

The use of values of c’,  ’ associated with peak failure leads to the prediction of impossible tensile stresses. It is generally more appropriate and safer to use ultimate or critical state parameters, c’ = 0,  ’ =  ’ ult Using the critical state parameters a larger active force is required for wall stability, and hence a safer estimate is obtained Effective Stress Analysis c’ = 0,  ’ =  ’ ult c’,  ’

For passive failure the horizontal stresses on a wall retaining dry sand are given by Effective Stress Analysis

For passive failure the horizontal stresses on a wall retaining dry sand are given by In this case the critical state parameters c’ = 0,  ’ =  ’ ult give a smaller force. However, this is a safe, conservative, estimate of the maximum force the soil can support. Effective Stress Analysis

For passive failure the horizontal stresses on a wall retaining dry sand are given by In this case the critical state parameters c’ = 0,  ’ =  ’ ult give a smaller force. However, this is a safe, conservative, estimate of the maximum force the soil can support. It is important to use effective vertical stresses,  v ’ =  v - u to calculate the effective horizontal stresses,  h ’. Then the total horizontal stress is given by  h =  h ’ - u Effective Stress Analysis

For passive failure the horizontal stresses on a wall retaining dry sand are given by In this case the critical state parameters c’ = 0,  ’ =  ’ ult give a smaller force. However, this is a safe, conservative, estimate of the maximum force the soil can support. It is important to use effective vertical stresses,  v ’ =  v - u to calculate the effective horizontal stresses,  h ’. Then the total horizontal stress is given by  h =  h ’ - u If the water level is not the same on both sides of a wall, water will flow. The pore pressures must then be determined from a flow net before calculating  v ’. Effective Stress Analysis

Example A 10 m high retaining wall retains 5 m of clay which overlays 3 m of sand which overlays 2 m of clay. The water table is at the surface of the retained soil. Calculate the limiting active pressure immediately after construction. 5m Clay 3m Sand 2m Clay c u = 20 kPa  u = 5 o  sat = 15 kN/m 3 c’ = 0  ’= 35 o  sat =20kN/m 3 c u = 50 kPa  u = 0 o  sat = 15 kN/m 3

Example - Short term analysis Layer 1: A clay layer so will be undrained in the short term. Will require a total stress (undrained) analysis

Example - Short term analysis Layer 1: A clay layer so will be undrained in the short term. Will require a total stress (undrained) analysis Active failure thus  1 =  v and  3 =  h

Example - Short term analysis Layer 1: A clay layer so will be undrained in the short term. Will require a total stress (undrained) analysis Active failure thus  1 =  v and  3 =  h From the Mohr-Coulomb failure criterion

Example - Short term analysis Layer 1: A clay layer so will be undrained in the short term. Will require a total stress (undrained) analysis Active failure thus  1 =  v and  3 =  h From the Mohr-Coulomb failure criterion At surface z = 0,  v = 0,  h = - 36.6 kPa At base of layer z = 5 m,  v = 5x15,  h = 26.4 kPa

Example - Short term analysis -36.6 26.4 Analysis predicts tensile stresses between the soil and the wall. These are not possible, and a tension crack may develop. z 0 = 2.91 m

Example - Short term analysis -36.6 26.4 Analysis predicts tensile stresses between the soil and the wall. These are not possible, and a tension crack may develop. Because the water table is at the surface the crack will fill with water, and a more pessimistic pressure distribution will be z 0 = 2.91 m

Example - Short term analysis -36.6 26.4 Analysis predicts tensile stresses between the soil and the wall. These are not possible, and a tension crack may develop. Because the water table is at the surface the crack will fill with water, and a more pessimistic pressure distribution will be 26.4 z 0 = 2.91 m  w z 9.81 x 2.91

Example - Short term analysis Layer 2: Sand so excess pore pressures will dissipate rapidly. Cannot use total stress analysis.

Example - Short term analysis Layer 2: Sand so excess pore pressures will dissipate rapidly. Cannot use total stress analysis. For sand in short term assume fully drained. Must use effective stress analysis.

Example - Short term analysis Layer 2: Sand so excess pore pressures will dissipate rapidly. Cannot use total stress analysis. For sand in short term assume fully drained. Must use effective stress analysis. Active failure so  ’ 1 =  ’ v and  ’ 3 =  ’ h and from the Mohr-Coulomb criterion

Example - Short term analysis Layer 2

Example - Short term analysis Layer 2 Note that most of horizontal pressure is due to water

Example - Short term analysis Layer 3: Clay, therefore total stress (undrained) analysis for short term

Example - Short term analysis Layer 3: Clay, therefore total stress (undrained) analysis for short term When  u = 0 the Mohr-Coulomb criterion reduces to  1 =  3 + 2 c u

Example - Short term analysis The final pressure distribution is 28.5 26.4 56 93.7 35 65 2.91 2.09 3 2

Example - Short term analysis The final pressure distribution is 28.5 26.4 56 93.7 35 65 2.91 2.09 3 2 The force required to prevent active failure can be determined from the pressure diagram F = 0.5x28.5x2.91 + 0.5x26.4x2.09 + 56x3 + 0.5x(93.7-56)x3 + 35x2 + 0.5x(65-35)x2 = 393.7 kN/m

Example 2 A 5m high retaining wall retains a clayey soil, which overlies a highly permeable sandstone. If the water level remains at the surface of the clay in the retained soil, and is level with the top of the sandstone determine the minimum force required to maintain the stability of the wall for short and long term. The soil parameters are: Clayey soil Sandstone 5 m

Example 2 - Short term Short term undrained - total stress analysis

Example 2 - Short term Short term undrained - total stress analysis Minimum force for stability - active failure

Example 2 - Short term Short term undrained - total stress analysis Minimum force for stability - active failure At surface  h = - 67.8 kPa, at 5 m  h = 11.9 kPa

Example 2 - Short term Short term undrained - total stress analysis Minimum force for stability - active failure At surface  h = - 67.8 kPa, at 5 m  h = 11.9 kPa Allowing for tension crack filling with water, pressures acting on the wall will be z o = 4.25 m 11.9 4.25x 9.81

Example 2 - Long term Long term - Effective stress analysis Pore pressures required - To be determined from a flow net

Example 2 - Long term Long term - Effective stress analysis Pore pressures required - To be determined from a flow net 5 m

Example 2 - Long term Long term - Effective stress analysis Pore pressures required - To be determined from a flow net 5 m Take datum at base of clay, then at X h = h o -  h = 5 - (5/3)x1 = 10/3 X

Example 2 - Long term Long term - Effective stress analysis Pore pressures required - To be determined from a flow net 5 m Take datum at base of clay, then at X h = h o -  h = 5 - (5/3)x1 = 10/3 z = (2/3)x5 = 10/3 u = 0 X

Example 2 - Long term Effective stress analysis with c’ = 0,  ’ = 25 o Now u = 0, so  ’ v =  v =  sat z At wall base  h =  ’ h = 38.6 kPa Hence F = 0.5 x 38.6 x 5 = 96.4 kN/m

Coulomb’s Method

Failure mechanism In Coulomb’s method a mechanism of failure has to be assumed Assumed failure plane wall movement soil movement

Failure mechanism In Coulomb’s method a mechanism of failure has to be assumed If this is the failure mechanism then the Mohr-Coulomb failure criterion must be satisfied on the assumed failure planes Assumed failure plane wall movement soil movement

The application of the failure criterion to assumed mechanisms of failure is widely used in geotechnical engineering. This is generally known as the limit equilibrium method. It is not a rigorous theoretical method but is used because it gives simple and reasonable estimates of collapse. The method has advantages over Rankine’s method –it can cope with any geometry –it can cope with applied loads –friction between soil and retaining walls (and other structural elements) can be accounted for Limit equilibrium method

Failure criterion For any point on the failure plane we have

Failure criterion For any point on the failure plane we have If analysis is of undrained stability then the failure criterion must be expressed in terms of total stress using undrained parameters c u and  u

Failure criterion For any point on the failure plane we have If analysis is of undrained stability then the failure criterion must be expressed in terms of total stress using undrained parameters c u and  u If the pore pressures are known or the soil is dry an effective stress analysis can be conducted and the failure criterion must be expressed in terms of effective stress and effective strength parameters c’,  ’

direction of soil movement Assumed failure plane   Failure criterion

direction of soil movement Assumed failure plane   Failure criterion Forces on the failure plane Shear Force T =

direction of soil movement Assumed failure plane   Failure criterion Forces on the failure plane Shear Force T = Normal Force N =

direction of soil movement Assumed failure plane   Failure criterion Forces on the failure plane Shear Force T = Normal Force N = Cohesive Force C =

Failure criterion If the soil properties are constant

Failure criterion If the soil properties are constant T N The forces acting on the failure plane are

Failure criterion If the soil properties are constant C  T N R The forces acting on the failure plane are which may be more convieniently represented by

Failure criterion For a wedge of soil failing as shown below there has to be relative movement between the wall and the soil, and the soil must be failing on this plane. Assumed failure planes wall movement soil movement

Failure criterion For a wedge of soil failing as shown below there has to be relative movement between the wall and the soil, and the soil must be failing on this plane. Assumed failure planes wall movement soil movement The failure criterion between the wall and the soil may be written

Failure criterion For a wedge of soil failing as shown below there has to be relative movement between the wall and the soil, and the soil must be failing on this plane. Assumed failure planes wall movement soil movement The failure criterion between the wall and the soil may be written or in terms of forces

A total stress analysis is only valid if the soil is saturated and does not drain In practice this generally means total stress analysis is limited to assessment of the short term stability of clayey soils Must use total stresses and undrained parameters c u,  u Total Stress Analysis

H  H sec  H tan  dir. of soil movement Soil properties c u,  u Soil-wall properties c w,  w

Total Stress Analysis - forces consistent with mechanism   w  u C 1 C 2 R 1 R 2 W C 1 = c u H sec  C 2 = c w H W = ½ H 2 tan  

Total Stress Analysis - polygon of forces  C 1 C 2 W

u   w C 1 C 2 W 

u Total Stress Analysis - polygon of forces   w C 1 C 2 R 1 R 2 W 

u Total Stress Analysis - polygon of forces   w C 1 C 2 R 1 R 2 W  In the polygon of forces arrows must all be in the same direction as you move around the polygon. A check must be made that the indicated directions are consistent with the failure mechanism

Total Stress Analysis - polygon of forces   w  u C 1 C 2 R 1 R 2 W

Total Stress Analysis - polygon of forces   w  u C 1 C 2 R 1 R 2 W Direction of R 2 is not consistent with assumed mechanism. Therefore the mechanism is not valid.

Total Stress Analysis - forces on the wall The polygon gives the forces acting on the soil wedge. Equal and opposite forces act on the wall. The forces acting on the wall will be

Total Stress Analysis - forces on the wall The polygon gives the forces acting on the soil wedge. Equal and opposite forces act on the wall. The forces acting on the wall will be  w R 2 C 2 F total

Total Stress Analysis - forces on the wall The polygon gives the forces acting on the soil wedge. Equal and opposite forces act on the wall. The forces acting on the wall will be  w R 2 C 2 V H F total F

Total Stress Analysis - forces on the wall The polygon gives the forces acting on the soil wedge. Equal and opposite forces act on the wall. The forces acting on the wall will be  w R 2 C 2 V H F total F For retaining walls the horizontal component of force is usually of most concern. For the active failure condition different values of  need to be tried to determine the maximum value of H.

Total Stress Analysis - tension cracks As with Rankine’s method allowance must be made for tension cracks, and if water is present the possibility that these cracks may fill with water.

Total Stress Analysis - tension cracks As with Rankine’s method allowance must be made for tension cracks, and if water is present the possibility that these cracks may fill with water. The depth, z, of the region affected by tension cracks can be determined from Rankine’s method. For active failure this gives

Total Stress Analysis - tension cracks H  z

  w  u C 1 * C 2 * R 1 * R 2 * W 2 W 1

If the tension cracks fill with water this has no influence on the polygon of forces.

Total Stress Analysis - tension cracks If the tension cracks fill with water this has no influence on the polygon of forces. The water will provide an additional horizontal force on the wall

Total Stress Analysis - Example 1 5 m 30 o dir of soil movement 10 o Soil Properties c u = 10 kPa  u = 10 o c w = 2 kPa  w = 20 o  = 20 kN/m 3 6.4 m U V W

Total Stress Analysis - Example 1

30 o 50 o 20 o 160 64 10 R uw = 60 kN/m

Effective Stress Analysis An effective stress analysis can be performed whenever the pore pressures are known.

Effective Stress Analysis An effective stress analysis can be performed whenever the pore pressures are known. In practice this usually means that effective stress analysis can only be used to assess the long term stability

Effective Stress Analysis An effective stress analysis can be performed whenever the pore pressures are known. In practice this usually means that effective stress analysis can only be used to assess the long term stability The failure criterion must be written in terms of effective stress, that is

Effective Stress Analysis An effective stress analysis can be performed whenever the pore pressures are known. In practice this usually means that effective stress analysis can only be used to assess the long term stability The failure criterion must be written in terms of effective stress, that is In terms of forces this becomes

Effective Stress Analysis An effective stress analysis can be performed whenever the pore pressures are known. In practice this usually means that effective stress analysis can only be used to assess the long term stability The failure criterion must be written in terms of effective stress, that is In terms of forces this becomes where N’ = N - U U = force due to water pressure on failure plane

Effective Stress Analysis - Forces on failure plane T N´ U Failure plane

Effective Stress Analysis - Forces on failure plane T N´ U C´  ´ U R´ Failure plane

When performing effective stress stability calculations the critical state parameters c’ = 0,  ’ =  ’ ult should be used When the soil is dry the pore pressures everywhere will be zero, and the effective stresses will equal the total stresses. However, only an effective stress analysis is appropriate. If sliding occurs between the soil and a wall appropriate effective stress failure parameters must be used. The effective parameters between any interface (eg. a wall) and the soil should be based on the ultimate conditions so that c´ w = 0,  ´ w =  ´ wult Effective Stress Analysis

In using Coulomb’s method you have to assume a failure mechanism. However, this may not be the most critical (least safe) mechanism. Therefore, you need to investigate a number of mechanisms (values of  ) to determine which will be the most critical. For Active failure the Maximum force is needed (Maximum of Minimum) For Passive failure the Minimum force is needed (Minimum of Maximum) The most critical mechanism is unlikely to give an accurate estimate of the failure load, because observation of real soil shows failure rarely occurs on planar surfaces. Effective Stress Analysis

To select a  value for the assumed failure plane in the soil it is helpful to remember that the failure plane is inclined at an angle (  /4 -  /2) to the direction of the minor principal stress  3. Effective Stress Analysis

33  Active

Effective Stress Analysis 33 33   Active Passive

In the presence of steady state seepage it may be necessary to draw a flow net to determine the pore water Forces U acting on the soil wedge. Effective Stress Analysis 33 33   Active Passive

Active failure  U V W C´ uv R´ uv R´ uw C´ uw W  ´ w  ´ U uv U uw Direction of movement of soil wedge

Passive failure  U V W R´ uw C´ uw W  ´ w U C´ uv U R´ uv  ´

Effective stress analysis - Example 5 m 30 o 10 o 6.4 m U V W W.T. X Water Soil Water 5 m

30 o 6.4 m U V W X Soil 5 m Effective stress analysis - Example

30 o 6.4 m U V W X Soil 5 m Effective stress analysis - Example Soil Properties c´ = 5 kPa  ´ = 10 o c´ w = 2 kPa  ´ w = 20 o  dry = 20 kN/m 3  sat = 22 kN/m 3

30 o 6.4 m U V W X Soil 5 m Effective stress analysis - Example C´ uv = 5  6.4 = 32 kN/m C´ uw = 2  5 = 10 kN/m Soil Properties c´ = 5 kPa  ´ = 10 o c´ w = 2 kPa  ´ w = 20 o  dry = 20 kN/m 3  sat = 22 kN/m 3

30 o 6.4 m U V W X Soil 5 m Effective stress analysis - Example C´ uv = 5  6.4 = 32 kN/m C´ uw = 2  5 = 10 kN/m W = 0.5  5  2.89  22 + (8 - 0.5  5  2.89)  20= 174.5 kN/m Soil Properties c´ = 5 kPa  ´ = 10 o c´ w = 2 kPa  ´ w = 20 o  dry = 20 kN/m 3  sat = 22 kN/m 3

Example - Water pressures on soil wedge U V W X

U V W X

Example - Forces on soil wedge R´ uv R´ uw U uw U uv C´ uv C´ uw W

Example - Polygon of forces R´ uv R´ uw U uw U uv C´ uv C´ uw W 30 o 60 o W C´ uv C´ uw U uv U uw

Example - Polygon of forces R´ uv R´ uw U uw U uv C´ uv C´ uw W 30 o 60 o o W C´ uv C´ uw U uv U uw

Example - Polygon of forces R´ uv R´ uw U uw U uv C´ uv C´ uw W

Example - Forces on the wall U uw R´ uw C´ uw

The vertical and horizontal components of the force on the wall are Vertical Example - Forces on the wall U uw R´ uw C´ uw T = R´ uw sin  ´ w + C´ uw = 5.8 + 10 = 15.8 kN/m

The vertical and horizontal components of the force on the wall are Vertical Horizontal Example - Forces on the wall U uw R´ uw C´ uw T = R´ uw sin  ´ w + C´ uw = 5.8 + 10 = 15.8 kN/m N uw = R´ uw cos  ´ w + U uw = 15.97 + 122.5 = 138.5 kN/m

The vertical and horizontal components of the force on the wall are Vertical Horizontal Note that N is largely due to water pressure. However, due to water on the other side of the wall the net resistance required for stability is only 15.97 kN/m Example - Forces on the wall U uw R´ uw C´ uw T = R´ uw sin  ´ w + C´ uw = 5.8 + 10 = 15.8 kN/m N uw = R´ uw cos  ´ w + U uw = 15.97 + 122.5 = 138.5 kN/m uw

Example 3

Choosing a local datum at E: h D = 0

Example 3 Choosing a local datum at E: h D = 0, z D = - x and u D = +  w x x

Example 3 The pore pressure at several points along the failure plane needs to be determined to evaluate the force due to the water pressures.

Example 3 The pore pressure at several points along the failure plane needs to be determined to evaluate the force due to the water pressures. The forces on the assumed failing soil wedge are then U w = 0.5  w H w 2 R´ w  ´ w W  ´ cs U From flow net

AÙp löïc chuû ñoäng vaø bò ñoäng cuûa ñaát rôøi

Thay ñoåi tyû soá aùp löïc ñaát ngang vaø ñöùng theo bieán daïng ngang trong thí nghieäm neùn ba truïc

Heä soá aùp löïc ñaát trong tröôøng hôïp maët ñaát nghieâng Heä soá aùp löïc ñaát trong tröøong hôïp löng töôøng nhaùm

Aùp löïc chuû ñoäng vaø bò ñoäng theo lyù thuyeát Coulomb

Phöông phaùp veõ Culmann

Aùp löïc ñaát theo lyù thuyeát Rankine Toång aùp löïc taùc ñoäng leân töôøng F = ½ (  w +K a  ’)H 2

Caùc phöông phaùp thöôøng söû duïng Tröøong hôïp coù nöôùc chaûy

Töôøng baûn coù doøng nöôùc

Xeùt taûi troïng ñoäng

Ñaøo töôøng ñuùc beâ toâng taïi choå

Chuyeån vò töôøng vaø traïng thaùi giôùi haïn cuûa ñaát

Traïng thaùi moment trong caùc giai ñoaïn thi coâng

Aùp löïc ñaát coù xeùt ñeán söï ñaàm chaët ñaát treân maët

HEÄ SOÁ AN TOAØN CHOÁNG TUOÄT HEÄ SOÁ AN TOAØN CHOÁNG ÑÖÙT

THÍ DUÏ: moät töôøng chaén cao 8m. Ñaát ñaép sau löng töôøng coù  = 16,6 KN/m 2 ;  = 30 0. Theùp Galvani ñöôïc söû duïng ñeå xaây töôøng chaén.Tính heä gia cöôøng vôùi FS 9p) = FS (B) = 3 Caùc ñaëc tröng khaùc  a = 20 0 vaø löïc chòu keùo cuûa theùp f y = 2,4  10 5 KN/m 2. GIAÛI: Choïn S V = 0,5m; S H = 1m; maët thanh theùp  = 75mm. Töø  = 30 0  K a = 1/3 T max =  HK a S V S H =16,6  8  (1/3)  0,5  1 = 22,14 KN Beà daày taám theùp Neáu theùp coù ñoä ró seùt 0,025mm/naêm vaø tuoåi thoï coâng trình laø 50 naêm Chieàu daày caàn thieát cuûa thanh theùp laø 3,69+0,025  50= 4,94mm choïn t= 5mm CHIEÀU DAØI CAÀN THIEÁT THANH GIA CÖÔØNG

Chöông 5 AÙp löïc ñaát – TÖÔØNG CHAÉN. Earth Pressures on Retaining walls Rankine’s Method.

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Chöông 5 AÙp löïc ñaát – TÖÔØNG CHAÉN. Earth Pressures on Retaining walls Rankine’s Method.

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Presentation on theme: "Chöông 5 AÙp löïc ñaát – TÖÔØNG CHAÉN. Earth Pressures on Retaining walls Rankine’s Method."— Presentation transcript:

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