Displacement Calculation Method on Front Wall of Covered Sheet-Pile Wharf

Covered sheet-pile wharves are widely used in port engineering, water conservancy, and civil engineering. /is paper is based on the theory of earth pressure and the soil arching effect. According to the stress and deformation characteristics of the covered sheet-pile wharf, the formulas used to calculate the force and deformation of the front wall of a covered sheet-pile wharf under static loads are deduced. /e accuracy of the theoretical derivation is verified by comparing actual measured stress and deformation data of Jingtang Port 32#. /e comparison shows that when calculating the displacement of the section below the mud surface boundary, the results are in agreement with the in situ data. However, when calculating the displacement of the section above the mud surface boundary, if the anchorage point displacement is ignored because the anchorage point displacement is limited artificially, the calculated tension of the tie rod is relatively large./is leads to a significant decrease in the calculation result of the section above the mud surface boundary, which is very different from actual in situ measurement results. If anchorage point displacement is considered, the calculated tension of the tie rod is more accurate, and the calculation results of the front wall displacement are very close to in situ measurement results because the anchorage point displacement is assumed scientifically.


Introduction
To develop sheet-pile wharves for deep water and large berths, China Railway First Survey and Design Institute has designed and researched wharves for many years, proposed a new type of covered sheet-pile wharf in 2002, and successfully built a 100 thousand ton deep-water berth wharf [1].
Sheet-pile wharf structures include front sheet-pile walls, covered piles, anchorage walls, tie rods, and wharf equipment.
e structure of a sheet-pile wharf is shown in Figure 1.It is characterized by adding a row of reinforced concrete cast-inplace piles [2], which is the covered pile, between the front walls and anchorage walls.e distance between the front sheet-pile walls is 3∼5 m.Usually, covered piles are arranged in intervals.Front sheet-pile walls, covered piles, and anchorage walls are connected as a whole structure by front and rear tie rods.e existence of covered piles resists soil pressure behind the wall and reduces the soil pressure acting directly on the front sheet-pile walls.Relevant studies have shown that under normal design conditions, covered piles reduce the positive and negative bending moment of front walls by approximately 70% and 10%, respectively, and do not have a great influence on anchorage wall forces [3].e application and development of the new type of covered sheet-pile wharf provides technical feasibility for developing sheet-pile wharves for deep water [4].Researchers have made great efforts to research seismic analysis of anchored sheet-pile wharf walls [6][7][8].Several theories and findings on the seismic analysis of sheet-pile wharves have been developed over the last several decades through experiments with shaking table tests [6,8,[9][10][11].A fundamental study on the simple evaluation method of the seismic performance of sheet-pile quay walls with vertical pile anchorage against level-one earthquake ground motion was proposed [12].e phenomenon of the large deformation of the sheet-pile quay wall and the failure of pile foundation due to liquefaction-induced lateral spreading in a port area were investigated [13][14][15].An optimization model for predicting the lateral displacement caused by liquefaction was formed by Kalantary [16].Mitigation measures can be taken for pile groups behind quay walls subjected to lateral ow of lique ed soil [17].e transfer formula for the horizontal thrust acting on the plane of covered sheet pile on land can be derived [17,18].Unfortunately, at present, research on covered sheet-pile wharf structures is super cial.To date, there are no systematic, reasonable, practical calculation method theories.
erefore, research on covered sheet-pile wharf structures has signi cant practical value.
In this paper, front wall displacement calculation was deduced theoretically based on the Winkler hypothesis.Soil pressure and displacement formulas of front sheet-pile walls in the deep part of the soil are calculated using the "m" method under static loads.Front sheet-pile walls in sheetpile wharf forces were calculated according to the active earth pressure theory.
e soil arching e ect theory was combined with the lateral pressure coe cient values of parallel wall soil by doctoral student Jiang [19], and the stress on the front walls of covered sheet-pile wharves was calculated.Displacement formulas for the deformation of the front walls of a sheet-pile wharf under static load were derived based on the de ection curve equation and deformation characteristics of the material mechanics.
Finally, using a relatively mature theory of static earth pressure and soil arching e ect theory, displacement formulas for the front wall of a covered sheet-pile wharf under static load are deduced and are compared with in situ observation data of the Jingtang Port 10# berth wharf and the Jingtang Port 32# wharf to verify the accuracy of the theoretical derivation.

Winkler's Assumption
In the elastic foundation reaction method based on Winkler's assumption, pile calculation assumes the ground reaction force p is proportional to the n-th power of the pile displacement y, that is, where y is the lateral de ection of the pile calculation point (m), h is the depth of the pile calculation point (m), and K(h) is the ground coe cient.
Matlock and Rees [20] noted that the ground coe cient K(h) should be as simple as possible, and two kinds of relations are suggested, namely, K(h) mh q , (2) Currently, according to some measured data and from the perspective of practicality and convenient analysis, the foundation coe cient K(h) is considered to change with a power-law function with depth h consistent with the actual depth, that is, where m is the proportional coe cient, while the foundation coe cient varies with depth, a is the pure values that change with rock type [21][22][23][24], and h 0 is a constant related to the category of rock soil.e values of m, a, and h must be determined by experiments.According to the di erent values of a, the law of foundation coe cient changing with depth in equation ( 1) can be drawn as shown in Figure 2.

Simpli ed Calculation Model and Earth Pressure Area
Distribution of Covered Sheet-Pile Wharf Structure.e covered sheet-pile wharf calculation model is composed of front sheet-pile walls, covered piles, anchorage walls, and front and rear tie rods, as shown in Figure 3.When calculating earth pressure, the soils are assumed to be in limit equilibrium, while the e ect of wave force is not considered.
e largest di erence between the covered sheet-pile wharf and the conventional sheet-pile wharf structure is that covered piles are set up between the front walls and anchorage walls, and covered piles resist the soil behind the piles and decrease the earth pressure loaded directly on the front walls.To analyse the e ects of covered piles in detail, soils are divided into ve regions to be discussed separately.Areas 1 and 4 are the front sheet-pile wall and covered pile, respectively, which are in soil.Since the horizontal displacement of the structure under static loads is relatively small, an elastic resistance method is adopted to calculate the horizontal earth pressure and the horizontal resistance coe cient depends on the "m" method.e earth pressure in areas 2 and 3 is more complex.Soils in these areas are between front sheet-pile walls and covered piles.e relative displacement between front sheet-pile walls and covered piles has an important in uence on the amount of earth pressure.In practical engineering design, covered pile sti ness is often designed to be larger to reduce the front wall earth pressure.As a result, front-wall displacement is greater than covered-pile displacement.Soils between front walls and covered piles tend to move towards the sea, and earth pressure is partial to an active state.erefore, earth pressure coe cients in areas 2 and 3 should be between the active earth pressure and stationary earth pressure.In this paper, Jiang Bo, a doctoral student at Zhejiang University, concluded that the lateral pressure coe cients of parallel wall  Advances in Civil Engineering soils should be used.Recommended lateral pressure coe cients are shown in Table 1.

Earth Pressure Calculation between Front Sheet-Pile Walls and Covered
Piles. e lateral earth pressure between front sheet-pile walls and covered piles is usually calculated using the parallel wall theory.When calculating, a unit wall width is taken along the front sheet-pile wall width in the horizontal direction.e distance between tie rods can also be selected as a calculation unit.In the vertical direction, the microcell d z is taken deep along the wall.en, force analyses of the microcell are carried out.e vertical stress σ z can be obtained using the equilibrium equation integral.e lateral earth pressure at any depth of the front sheet-pile wall can be obtained by multiplying the vertical stress σ z by the lateral pressure coe cient K w [25].
According to the parallel wall theory, along the length of a parallel wall cross section, at any depth z, thickness B is used in microsoil, as shown in Figure 4. e unit width is calculated to analyse the microsoil forces: (1) Soil weight, dW: ( (2) Upper and lower surface pressure of microsoil: Vertical pressure of upper surface: Vertical pressure of lower surface: (3) Friction near microsoil: where δ is the friction angle of soils near the front sheet-pile walls.e friction angle can be selected according to roughness and drainage conditions: (1) Smooth and poorly drained, δ (0 ∼(1/3))ϕ (2) Rough and well drained, δ ((1/3) ∼(1/2))ϕ (3) Very rough and well drained, δ ((1/2)∼ (2/3))ϕ e above equilibrium equation can be obtained according to a vertical force balance of microelements: Boundary condition: Taking equation ( 12) into account, e above formulas do not take cohesive forces of clay soils into account.erefore, when the soil is clay, internal forces generated by cohesive force c should be considered.e internal force σ c c cot φ produced by cohesive force c is regarded approximately as a uniform force on the boundary surfaces of the soils, substituting it into equation ( 13), the calculation formula for σ z in clay soils can be obtained:

Force Calculation of Front Walls Transmitted from Soils between Covered Piles.
According to previous research results, the soil arch between piles can be divided into two parts, as shown in Figure 5. e earth pressure in the distance is assumed to be transferred to adjacent covered piles through the outer arch area and stable inner arch area, and front sheet-pile walls can be used as a pair of parallel walls.When the pressure line of the arch coincides with the arch axis, the bending moment of each section is zero, and arches have no bending moment and the material cost is the most economical.Since the three-   4 Advances in Civil Engineering hinged arch structure and loads are symmetrical, half of the three-hinged arch is considered as the research object.e coordinate system is set up as shown in Figure 6. e equation for a reasonable arch axis is Reaction force of the arch foot: Combined with R x � R y tan δ, the equation for the reasonable arch axis is calculated by where l is the arch span, f is the arch height, and δ is the friction angle.
Along the vertical direction, at any depth z, microsoil with a thickness of dz is taken, as shown in Figure 7. Forces acting on microsoils in the vertical direction are as follows: Gravity: where s � (L + f)l.
Friction between the soils and front sheet-pile walls: Soil friction at soil arches: Earth pressure difference between the upper and lower surfaces: Vertical force equilibrium equation of microsoils: where σ z and σ y are the vertical stress and horizontal stress, respectively.e forces transmitted from the soils in the arches to the front sheet-pile walls are assumed to be evenly distributed on the horizontal plane.Forces are distributed in the vertical direction according to lateral pressure coefficient K w � σ y /σ z .Combined with the above formulas, the following formula is obtained: According to the analytic theory of differential equations, the following formula can be obtained: Boundary condition: Substituting equation (25) into equation ( 24), the following formula is obtained: e above formulas do not take cohesive forces of clay soils into account.
erefore, when the soil is clay, the e internal force σ c � c cot φ produced by cohesive force c is considered an approximately uniform force on the boundary surfaces of the soils.Substituting this force into equation ( 27), the calculation formula for σ z in clay soils can be obtained: e earth pressure on the front sheet-pile walls, which are close to land, is calculated by

Earth Pressure on Front Sheet-Pile Walls beneath Mud
Surface.When calculating the earth pressure on the front sheet-pile walls, which are below the mud surface, considering the stiffness of the covered sheet-pile wharves under static loads is large but the horizontal displacement generated by the structure is relatively small, and an elastic resistance method is adopted, that is, the soil horizontal resistance at any depth z is proportional to the soil horizontal displacement y, that is, Currently, the "m" method is adopted in port engineering in China to determinate the horizontal resistance coefficient K Z .Assuming the earth resistance coefficient increases linearly with depth, Substituting equation (31) into equation (30), P z is computed by (32)

Earth Pressure on Front Sheet-Pile Walls above Mud
Surface. e displacement calculation for front sheet-pile walls of covered sheet-pile wharves is the same as for traditional sheet-pile wharves.Since the stress characteristics and deformation mechanism of front sheet-pile walls, which are in soils, are completely different from those above the mud surface, the front sheet-pile wall is divided into upper and lower parts at the mud surface for separate calculations.Below the mud surface, the sheet-pile walls can be simplified as elastic structures buried in soil, with the top layer being flat with the mud surface.e pile top has moment M 0 and lateral force Q 0 .M 0 and Q 0 are the resultant moment and force of the sheet-pile wall mud surface from the force above the sheet-pile wall mud surface.
e rotation angle and displacement of the pile top are φ 0 and y 0 , respectively.According to the previous description, when a pile lateral displacement y occurs at depth z, the soil resistance force acting on the piles at depth z is e overloaded soil pressure and residual water pressure above the mud surface are assumed to be uniform external loads.e overloaded soil pressure is averagely distributed according to the soil width between covered piles and behind covered piles and has a value q ′ that is calculated by where b is the covered pile width (m), l 1 is the covered pile net distance (m), σ yn is the horizontal earth pressure generated by soils between covered piles and front sheet-pile walls at the mud surface, and c n and φ n are the cohesive force (kPa) and the internal friction angle ( °) at the mud surface, respectively.Considering the conversion depth (h � α(z − H 1 )), based on the deflection curve differential equation in material mechanics, the following formulas are obtained: Substituting equation (33) into equation ( 35), Boundary conditions: According to the analytical theory of differential equations, the solution of equation (36) can be expressed by the following power series: e following formula can be obtained by derivation: Combined with the bottom boundary conditions: M � 0, Q � 0, the initial displacement y 0 and initial rotation angle φ 0 at the mud surface are calculated separately as 6 Advances in Civil Engineering e shear force Q 0 and bending moment M 0 of front sheet-pile walls at the mud surface should be calculated accumulatively: where z i is the distance from the bottom of the i-th layer to the wharf surface (m), l i is the distance from the earth pressure point of the i-th layer to the front mud surface (m).

Displacement Calculation of Front Wall When Anchorage
Point Displacement Is Ignored.e dynamic water load is a variable parameter and it is also helpful to reduce the displacement of the front wall sheet-pile wharf.erefore, in the paper, the calculation method of displacement on front wall was deduced considering the most dangerous situation without dynamic water load.
When the strength of the covered pile or anchorage structure is sufficient, the displacement of the upper part of front sheet-pile walls is smaller, displacement in the middle and lower part is larger, front sheet-pile walls tend to rotate around the anchorage point, and displacement at the anchorage point is negligible compared to the bottom displacement.Displacement at the anchorage point is assumed to be zero when tie rod tension and front wall displacement are solved, and the solution process is as follows.
e displacement of the front sheet-pile wall at the anchorage point primarily consists of four parts: displacement y 0 at the mud surface, displacement caused by rotation φ 0 at the mud surface, displacement Δ of front sheet-pile wall at the anchorage point caused by earth pressure behind the wall, and displacement f of front sheet-pile wall at the anchorage point caused by tie rod tension.Displacement of the front sheet-pile wall at the anchorage point is assumed to be zero.e following formula is obtained: (1) Calculate displacement f.
According to material mechanics formula: Boundary conditions: Combined with the boundary conditions, the formula solution is expressed by Converting equation (49) to a formula with depth z as a variable, the formula is expressed by (2) Calculate displacement Δ.
According to the material mechanics formula: Boundary conditions:

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In summary, displacement f and Δ are expressed by − bcK w cot φz 4  24 e displacement at any point of the front sheet-pile wall above the mud surface can be expressed by Finally, formulas to calculate the displacement of any point on the front sheet-pile wall above the mud surface can be expressed by

Considering Displacement of Anchorage Point to Calculate
Front Wall Displacement.When the strength of the covered pile or anchorage structure is insufficient, the displacement of the upper part of the front sheet-pile walls is larger, displacement at the bottom part is smaller, front sheet-pile walls tend to rotate around the front sheet-pile wall bottom, and displacement at the anchorage point is not negligible.e displacement at the anchorage point is assumed to have a specific value when the tie rod tension and front wall displacement are calculated, and the solution process is as follows.
e displacement at the anchorage point is y a .Substituting this into equation (57), the following equation is obtained: e following formula is recommended to determine y a : Displacement at any point of the front sheet-pile walls above the mud surface can be expressed by (61) Finally, the displacement at any point above the mud surface of the front sheet-pile walls can be expressed by

Flow Chart of Front Wall Displacement Calculation.
A flow chart of the displacement calculation process for the front walls of covered sheet-pile wharves under static loads is shown in Figure 8.

Example of Displacement Calculation for
Front Wall of Covered Sheet-Pile Wharf e observation results are shown in Table 3.

eoretical Calculation Results
. According to the displacement calculation theory for the front wall of a covered sheet-pile wharf under static loads, the displacement of the front wall when displacement at the anchorage point is neglected or considered is shown in Table 4.

Comparison and Analysis of Calculation Results.
e theoretical calculation and in situ measurement results for the front sheet-pile wall displacement of a covered sheet-pile wharf are shown in Figure 10.
From the figure, whether the displacement at the anchor point is considered or neglected has little effect on the displacement calculation of the front sheet-pile wall, which is below the mud surface.e results obtained using two calculation methods are close to measured data.e results of the two calculation methods are very different when calculating the displacement of the front sheet-pile wall, which is below the mud surface.When displacement at the anchorage point is ignored, the displacement at the anchorage point is limited artificially; therefore, the calculation result of tie rod tension is relatively large, which leads to the displacement calculation of the front wall above the mud surface being greatly reduced.e deformation mode of the front sheet-pile wall is a middle convex drum, and the maximum displacement is approximately 20 mm, which is very different from actual in situ measurement results.
When considering displacement at the anchorage point, the calculated tie rod tension is more accurate and the front wall displacement calculation is very close to the in situ measurement result because the anchorage point displacement is assumed scientifically.e upper part of the front wall is partially Advances in Civil Engineering restrained in an inclined deformation mode.e maximum displacement at the anchorage point of the front wall is approximately 55 mm, the measured maximum displacement is approximately 60 mm, and the error is 8.33%, which is ideal.In conclusion, it is more scienti c to use the hypothetical anchorage point displacement proposed in this paper.

Conclusion
is paper is based on the theory of soil pressure and the soil arching e ect.According to the stress and deformation characteristics of a covered sheet-pile wharf, the formulas used to calculate the force and deformation of the front wall of a covered sheet-pile wharf under static loads are deduced, and a comparison of actual measured stress and deformation data of Jingtang Port 32# is used to verify the accuracy of the theoretical derivation.
e comparison shows that when calculating the displacement of the front sheet-pile wall, which is below the mud surface, the results of the two methods are not very di erent and are in good agreement with eld measured data.However, when the displacement of the front sheet-pile wall is calculated, which is above the  Advances in Civil Engineering mud surface, and when displacement at the anchorage point is ignored, displacement at the anchorage point is limited artificially.erefore, the result of tie rod tension is relatively large, which leads to the calculated displacement of the front  Advances in Civil Engineering sheet-pile wall, which is above the mud surface, being greatly reduced.e deformation mode of the front sheet-pile wall is a middle convex drum, and the maximum displacement is approximately 20 mm, which is very different from the actual in situ measurement results.When displacement at the anchorage point is considered, the calculated tie rod tension is more accurate, and the results of the front wall displacement are very close to in situ measurement results because displacement at the anchorage point is assumed scientifically.e upper part of the front wall is partially restrained in an inclined deformation mode.e maximum displacement at the anchorage point of the front wall is approximately 55 mm, the measured maximum displacement is approximately 60 mm, and the error is 8.33%, which is ideal.In conclusion, it is more scientific to use the hypothetical anchorage point displacement proposed in this paper.

Figure 2 :Figure 3 :
Figure 2: Law of foundation coe cient changing with depth.

Figure 6 :Figure 7 :
Figure 6: Diagram of soil arch subjected to forces.

Figure 10 :
Figure 10: Comparison of two methods and measured data.

Table 1 :
Reference values of lateral pressure coefficient K w .
4.1.Project Overview.ecalculationmodel is based on the Jingtang Port 32# wharf.efrontwallsandanchoragewall structure are continuous underground walls.edistance between covered piles is 1.2 m, and the cross-sectional form is shown in Figure9.e soil, wall, and tie rod parameters are shown in Table2.eNanjing Hydraulic Research Institute organized relevant personnel to complete the installation of the instrumentation in February 2005, and the observation period was from June 2005 to February 2008.

Table 2 :
Soil, wall, and tie rod parameters.

Table 3 :
In situ measured data.

Table 4 :
Data for displacement of front pile wall.