REINFORCEMENT AND BEARING CAPACITY CALCULATION METHOD FOR SELF-STRESSED BRIDGE DECK LINK SLAB

Abstract

A reinforcement and bearing capacity calculation method for a self-stressed bridge deck link slab includes: calculating a cross-section moment of inertia of the link slab and a negative moment borne by the link slab; introducing a design self-stress according to stress distribution of the self-stressed bridge deck link slab, whether reinforced or un-reinforced; calculating a cracking moment of the plain self-stressed bridge deck link slab, comparing the cracking moment and the negative moment, proceeding to the next step, or configuring a structural reinforcement as needed; determining a design strength of reinforcement, selecting a reinforcement ratio, and calculating a resisting moment of the link slab; comparing the resisting moment and the negative moment of the link slab, design conditions are satisfied, or configuring the reinforcement ratio and carrying out iterative calculation to obtain a resisting moment; and analyzing stress on the reinforcement and concrete.

Claims

1. A reinforcement and bearing capacity calculation method for a self-stressed bridge deck link slab, comprising the following steps: (i) calculating a cross-section moment of inertia of the self-stressed bridge deck link slab and a negative moment M.sub.a borne by the link slab; (ii) introducing a design self-stress according to stress distribution of the self-stressed bridge deck link slab, whether reinforced or un-reinforced, in a continuous bridge structure; (ii) introducing a self-stress in a case that the self-stressed bridge deck link slab is un-reinforced, calculating a cracking moment M.sub.cr of the plain self-stressed bridge deck link slab, comparing the cracking moment M.sub.cr and the negative moment M.sub.a, and if M.sub.a≥M.sub.cr, proceeding to step (iv), otherwise, configuring a structural reinforcement as needed, and proceeding directly to step (vi); (iv) determining a design strength of reinforcement, selecting a reinforcement ratio, and calculating a resisting moment M.sub.u of the self-stressed bridge deck link slab; (v) comparing the resisting moment M.sub.u and the negative moment M.sub.a, and if M.sub.u≥M.sub.a, indicating that design conditions are satisfied, otherwise, configuring the reinforcement ratio and carrying out iterative calculation to obtain a resisting moment M.sub.u satisfying the conditions; and (vi) analyzing stress on the reinforcement and concrete to complete design.

2. The reinforcement and bearing capacity calculation method for the self-stressed bridge deck link slab according to claim 1, wherein in step (i), firstly, a length L.sub.ls of the self-stressed bridge deck link slab and a length L.sub.dz of a debonding strip are determined according to spans of a simply supported beam bridge, the length of the link slab being 0.075 times of the sum of two adjacent spans, and the length of the debonding strip being 0.05 times of the sum of two adjacent spans; a rotation angle at beam ends is determined according to 1/600 of a maximum span of the simply supported beam bridge, i.e., the rotation angle at beam ends is ${\theta }_{\max }=\frac{3}{L}.Math.\frac{L}{600},$ the cross-section moment of inertia of the link slab is determined according to a width b and a height h of the link slab, i.e., $I_{1s}=\frac{{\mathrm{bh}}^3}{12},$ and the negative moment borne by the link slab is determined from the cross-section moment of inertia and the rotation angle at beam ends, i.e., $M_a=\frac{3E_c{I}_{\mathrm{ls}}}{L_{\mathrm{dz}}}{\theta }_{\max },$ where L is a calculated span of the simply supported beam bridge, and E.sub.c is an elastic modulus of self-stressed concrete.

3. The reinforcement and bearing capacity calculation method for the self-stressed bridge deck link slab according to claim 1, wherein in step (ii), the self-stress is introduced using the following calculation formula: $\{\begin{array}{c}{f}_{\mathrm{sx}}^{\prime }=E_{c,t_{\left(j-i\right)/2}}{\epsilon }_{c,s}+\Delta f_{\mathrm{st}}^{\prime }\mathrm{in}\mathrm{the}\mathrm{reinforced}\mathrm{state}\mathrm{of}\mathrm{the}\mathrm{link}\mathrm{slab}\\ f_{\mathrm{sx}}=f_{\mathrm{sp}}+\Delta f_{\mathrm{st}}\mathrm{in}\mathrm{the}\mathrm{un}-\mathrm{reinforced}\mathrm{state}\mathrm{of}\mathrm{the}\mathrm{link}\mathrm{slab}\end{array}$ where f.sub.sx′ is a design self-stress of the link slab in an un-reinforced state, E.sub.c, t.sub.(j−i)/2 is an elastic modulus of the expansive concrete at a moment (j−i)/2, ε.sub.cs is an expansive deformation of the expansive concrete under constraints of the continuous structure, and equals to a free expansive deformation of the expansive concrete minus an elastic shrinkage deformation and a creep deformation of the expansive concrete, which is represented as ε.sub.c,s=ε.sub.c,0−ε.sub.c,el−ε.sub.c,cr, where ε.sub.c,0 is the free expansive deformation of the expansive concrete, ε.sub.c,el is the elastic shrinkage deformation of the expansive concrete, and ε.sub.c,cr is the creep deformation of the expansive concrete; Δf.sub.st′ is a variation of stress caused by a variation of temperature of the plain expansive concrete link slab, Δf.sub.st′ =E.sub.c,t(T−T.sub.sj)α.sub.c, where E.sub.c,t is an elastic modulus of the expansive concrete at a moment t, $E_{c,t}=\sqrt{\frac{t}{c_1+c_{2}t}}{E}_{c,28},$ T is a temperature of a region where the self-stressed bridge deck link slab is casted, T.sub.sj is a temperature under laboratory conditions, taken as 20° C., t is the age, c.sub.1 and c.sub.1 are constants, E.sub.c,28 is an elastic modulus of the expansive concrete at the age of 28 days, and α.sub.c is a linear expansion coefficient of the self-stressed concrete; f.sub.sx is a design self-stress of the link slab in a reinforced state, f.sub.sp is a variation of stress caused by a variation of reinforcement ratio of the link slab, f.sub.sp=ρ.sub.xE.sub.sε.sub.sx, where ρ.sub.x is the reinforcement ratio of the link slab, E.sub.s is an elastic modulus of the reinforcement, and ε.sub.sx is a constrained expansive deformation produced by the link slab with different reinforcement ratios, and the constrained expansive deformation varies with the reinforcement ratio in different reinforcement ratio ranges in the following law: $\{\begin{array}{cc}{\epsilon }_{\mathrm{sx}}=A-100B{\rho }_x+100\ln C{\rho }_x^2& 0.5\%\le \rho \le 1.5\%\\ {\epsilon }_{\mathrm{sx}}={\mathrm{De}}^{-\alpha {\rho }_x}& 1.5\%<\rho \end{array}$ the values of A, B, C and D in the formula are obtained by measuring the constrained expansive deformation according to the standard Expansive Agents for Concrete (GB/T 23439-2017), wherein the strain is measured by varying the diameter of the reinforcement, i.e., varying the reinforcement ratio of the self-stressed concrete, and as the reinforcement ratio increased, the constrained deformation varies in a binary linear law or exponential law with 1.5% as a boundary, and the values of A, B, C and D are obtained by curve fitting of the variation law of the constrained expansive deformation with the reinforcement ratio; Δf.sub.st′ is a variation of stress caused by a variation of temperature of the expansive concrete link slab in the reinforced state, $\Delta f_{\mathrm{st}}=\frac{{\rho }_x{E}_s\left(T-T_{\mathrm{sj}}\right)}{1+{\alpha }_E{\rho }_x}\left({\alpha }_c-{\alpha }_s\right),$ where α.sub.s is a linear expansion coefficient of the reinforcement, and α.sub.E is a ratio of the elastic modulus of the reinforcement to the elastic modulus of concrete.

4. The reinforcement and bearing capacity calculation method for the self-stressed bridge deck link slab according to claim 3, wherein in step (iii), the calculating a cracking moment M.sub.cr of the plain self-stressed bridge deck link slab comprises: a) when calculating the cracking moment, introducing the self-stress f.sub.sx′ according to a uniform compressive pre-stress caused by surrounding constraints of the link slab on a cross section of the link slab, and calculating a horizontal pressure on the cross section of the concrete in an initial state: Fsx=.sub.sx′bh; b) calculating a decompression moment: M.sub.0=f.sub.sx′.Math.W.sub.o=⅙f.sub.sx′bh.sup.2; c) according to a horizontal force balance equation of concrete stress states: $\frac{{\mathrm{bx}}^2}{h-x}{f}_{\mathrm{td}}=\frac{3}{4}b\left(h-x\right)f_{\mathrm{td}},$ calculating the cracking moment of a concrete link slab: M.sub.cr,c=0.256f.sub.tdbh.sup.2; and d) calculating the cracking moment of the self-stressed concrete link slab: M.sub.cr=0.256f.sub.tdbh.sup.2+⅙f.sub.sx′bh.sup.2; where f.sub.td is a design axial tensile strength of concrete; W.sub.o is an inertia resisting moment of concrete; x is a distance between a bottom surface and a neutral axis of the link slab.

5. The reinforcement and bearing capacity calculation method for the self-stressed bridge deck link slab according to claim 4, wherein in step (iv), the process of determining a design strength of reinforcement comprises: A) according to a stress-strain relationship of self-stressed concrete and reinforcement, defining the following physical equation:
f.sub.td=E.sub.cε.sub.t0=0.5E.sub.cε.sub.tu
f.sub.y=E.sub.sε.sub.s−f.sub.ss where f.sub.td is a design axial tensile strength of concrete; E.sub.c is an elastic modulus of self-stressed concrete; ε.sub.t0 is a tensile strain at yield of self-stressed concrete; ε.sub.tu is an ultimate tensile strain of self-stressed concrete; E.sub.s is the elastic modulus of the reinforcement; ε.sub.s is a strain of the reinforcement under load; f.sub.y is a stress produced when the strain of the reinforcement is ε.sub.s; f.sub.ss is a stress loss caused by stress relaxation of the reinforcement under self-stress, and if f.sub.ss/f.sub.pk≤0.5, f.sub.pk being an ultimate tensile strength of reinforcement, f.sub.ss is 0, and if f.sub.ss/f.sub.pk>0.5, f.sub.ss is determined with reference to the Chinese specification Technical Specifications for Construction of Highway Bridges and Culverts; and B) setting an upper limit strength of reinforcement as 40% of the yield strength, namely f.sub.y≤0.4f.sub.sd, calculating the strain of the reinforcement, and when the strain reaches the ultimate tensile strain of concrete ε.sub.tu, determining whether or not σ.sub.s=E.sub.sε.sub.tu is greater than or equal to 0.4f.sub.sd, and if not, namely σ.sub.s=E.sub.sε.sub.tu is less than 0.4f.sub.sd, then taking the design strength of reinforcement asμ times of the yield strength $\mu =\frac{E_s{\epsilon }_{\mathrm{tu}}}{f_{\mathrm{sd}}};$ if so, namely σ.sub.s=E.sub.sε.sub.tu is greater than or equal to 0.4f.sub.sd, taking the design strength of reinforcement as 40% of the yield strength.

6. The reinforcement and bearing capacity calculation method for the self-stressed bridge deck link slab according to claim 5, wherein the step (iv) comprises: I) when the design strength of reinforcement is μ times of the yield strength, taking the reinforcement ratio as ρ, and establishing an horizontal force balance equation of the cross section of the link slab as follows: $\frac{1}{2}\mathrm{bx}.Math.\frac{x}{h-x}.Math.2f_{\mathrm{td}}=\frac{3}{4}b\left(h-x\right)f_{\mathrm{td}}+f_{\mathrm{sx}}b\left(h-x\right)+\mu \left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)$ where $\frac{1}{2}\mathrm{bx}.Math.\frac{x}{h-x}.Math.2f_{\mathrm{td}}$ is a compressive stress of the self-stressed concrete, ¾b(h−x)f.sub.td is a tensile stress of the self-stressed concrete, f.sub.sxb(h−x) is a self-stress of the self-stressed concrete, and μ(ρf.sub.sdbh−f.sub.ss) is a tensile stress of the reinforcement; and calculating x according to a force balance equation, summing moments produced by four forces with respect to the neutral axis, and calculating a resisting moment of the bearing capacity of the link slab: $M_u=\frac{1}{2}\mu \left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)\left(h-x\right)+f_{\mathrm{sx}}b\frac{{\left(h-x\right)}^2}{2}+\frac{11}{24}{b\left(h-x\right)}^2{f}_{\mathrm{td}}+\frac{2}{3}\left(\frac{{\mathrm{bx}}^3}{h-x}\right)f_{\mathrm{td}};$ II) when the design strength of reinforcement is 40% of the yield strength, namely the concrete is in an elastic or elastic-plastic stage, establishing a horizontal force balance equation in such condition: $\frac{1}{2}\mathrm{bx}.Math.\frac{x}{h-x}.Math.2f_{\mathrm{td}}=\frac{3}{4}b\left(h-x\right)f_{\mathrm{td}}+f_{\mathrm{sx}}b\left(h-x\right)+0.4\left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)$ summing moments produced by four forces with respect to the neutral axis, and calculating a resisting moment of the bearing capacity of the link slab: $M_u=\frac{1}{2}.Math.0.4.Math.\left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)\left(h-x\right)+f_{\mathrm{sx}}b\frac{{\left(h-x\right)}^2}{2}+\frac{11}{24}{b\left(h-x\right)}^2{f}_{\mathrm{td}}+\frac{2}{3}\left(\frac{{\mathrm{bx}}^3}{h-x}\right)f_{\mathrm{td}}.$

7. The reinforcement and bearing capacity calculation method for the self-stressed bridge deck link slab according to claim 6, wherein the step (vi) specifically comprises: calculating respective tensile and compressive stresses of the reinforcement and the concrete under an actual stress conditions according to stress-strain distribution of the link slab with a design reinforcement, analyzing whether or not the stresses of the reinforcement and the concrete under load exceed stresses bearable by the reinforcement and the concrete, and determining whether or not the link slab cracks; wherein the stress bearable by the reinforcement is the yield strength of the reinforcement f.sub.sd, the tensile stress bearable by the concrete is the design axial tensile strength of the self-stressed concrete f.sub.td, and the compressive stress bearable by the concrete is the design axial compressive strength of the self-stressed concrete f.sub.cd; the tensile stress of the self-stressed concrete is: ${\sigma }_{c1}=\frac{M_a\left(h-x\right)}{I_{\mathrm{conversion}}}-f_{\mathrm{sx}};$ the compressive stress of the self-stressed concrete is: ${\sigma }_{\mathrm{cy}}=\frac{M_{a}x}{I_{\mathrm{conversion}}};$ the tensile stress of the reinforcement is: ${\sigma }_{s1}=2{\alpha }_E\frac{M_a\left(h-x\right)}{I_{\mathrm{conversion}}}+f_{\mathrm{ss}};$ in the formulas, the tensile stress of the self-stressed concrete is a tensile stress of the concrete caused by external load minus a compressive pre-stress of the self-stressed concrete caused by constraints of the reinforcement; the tensile stress of the reinforcement is a tensile stress of concrete caused by external load plus a stress loss caused by constraints of the reinforcement on the expansion of the self-stressed concrete; $I_{\mathrm{conversion}}=\frac{\left(1-\rho \right){\mathrm{bh}}^3}{12}+2{\alpha }_E\rho {\mathrm{bh}\left(h-x\right)}^2,{\alpha }_E=\frac{E_s}{E_c}.$

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0071] FIG. 1 is a schematic diagram of a simply supported beam bridge deck link slab;

[0072] FIG. 2 is a schematic diagram showing the stress condition of the self-stressed bridge deck link slab in an un-reinforced state;

[0073] FIG. 3 is a schematic diagram showing the stress condition of a self-stressed bridge deck link slab in a reinforced state;

[0074] FIG. 4 is a flow chart of a reinforcement and bearing capacity calculation method for a self-stressed bridge deck link slab;

[0075] FIG. 5 is a schematic diagram showing the stress-strain constitutive relationship of self-

[0076] stressed concrete and reinforcement in tension, in which (a) is concrete and (b) is reinforcement;

[0077] FIG. 6 is a schematic diagram showing the stress-strain variation relationship of the stress cracking of the cross section of the self-stressed concrete link slab, in which (a) is the distribution of the cross section, (b) is the distribution of strain, (c) is the distribution of prestress, (d) is a decompression stress, (e) is the distribution of stress when the crack is imminent, and (f) is a calculated stress diagram;

[0078] FIG. 7 is a schematic diagram showing the stress-strain variation relationship of the stress cracking of the cross section of the conventional tensioned reinforced pre-stressed concrete link slab, in which (a) is the distribution of the cross section, (b) is the distribution of strain, (c) is the distribution of prestress, (d) is the stress acting on the load, (e) is the stress under load, (f) is a decompression stress, and (g) is a calculated stress diagram; and

[0079] FIG. 8 is a schematic diagram showing the stress-strain variation relationship of the stress cracking of the cross section of the self-stressed reinforced concrete link slab, in which (a) is the distribution of the cross section, (b) is the distribution of strain, (c) is the distribution of prestress, (d) is the stress under pressure relief, (e) is the distribution of stress when the crack is imminent, and (f) is a calculated stress diagram.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0080] In order that the technical problems, technical solutions and advantages to be solved by the present disclosure will become more apparent, a detailed description will be given below with reference to the accompanying drawings and specific embodiments, but is not limited thereto. What is not described in detail in the present invention may be refereed as conventional techniques in the art.

Embodiment 1

[0081] A reinforcement and bearing capacity calculation method for a self-stressed bridge deck link slab, as shown in FIGS. 1 to 8, includes the following steps: [0082] (1) A cross-section moment of inertia of the link slab and a negative moment M.sub.a borne by the link slab are calculated.

[0083] Firstly, a length L.sub.ls of the link slab and a length L.sub.dz of a debonding strip are determined according to spans of a simply supported beam bridge, the length of the link slab being 0.075 times of the sum of two adjacent spans, and the length of the debonding strip being 0.05 times of the sum of two adjacent spans; [0084] a rotation angle at beam ends is determined according to 1/600 of a maximum span of the simply supported beam bridge, i.e., the rotation angle at beam end is

[00019]${\theta }_{\max }=\frac{3}{L}.Math.\frac{L}{600},$ [0085] the cross-section moment of inertia of the link slab is determined according to a width b and a height h of the link slab, i.e.,

[00020]$I_{\mathrm{ls}}=\frac{{\mathrm{bh}}^3}{12},$ [0086] and the negative moment borne by the link slab is determined from the cross-section moment of inertia and the rotation angle at beam ends i.e.,

[00021]$M_a=\frac{2E_c{I}_{\mathrm{ls}}}{L_{\mathrm{dz}}}{\theta }_{\max },$ [0087] where L is a calculated span of the simply supported beam bridge, and E.sub.c is an elastic modulus of self-stressed concrete. [0088] (2) A design self-stress is introduced according to stress distribution (as shown in FIGS. 2 and 3) of the self-stressed bridge deck link slab, whether reinforced or un-reinforced, in a continuous bridge structure.

[0089] The introduction of the self-stress takes into account the following assumptions: [0090] (1) the variation of temperature has little effect on the elastic modulus of the self-stressed concrete, and the elastic modulus increases logarithmically with time; [0091] (2) the two ends of the self-stressed concrete link slab are subjected to semi-rigid constraints under the action of an ordinary concrete bridge deck pavement; [0092] (3) the reduced expansive deformation of the link slab under the constraints of ordinary concrete is equal to a free expansive deformation of the link slab minus an elastic shrinkage deformation and a creep deformation of the link slab under stress; [0093] (4) at a moment i, an initial contact state between the self-stressed concrete link slab and the ordinary concrete bridge deck pavement is obtained, i.e., the compressive strength of the self-stressed concrete reaches a certain value, and the expansive deformation of the self-stressed concrete begins to produce the self-stress; [0094] (5) at a moment j, the free expansive deformation of the self-stressed concrete is approximately stable, and the expansive deformation no longer increases; and [0095] (6) the self-stress of the link slab in the un-reinforced state is uniformly distributed in the cross section of the link slab, and in the reinforced state, in view of safety, only the self-stress distributed near the reinforcement region of the link slab is considered, while in the present disclosure, the self-stress is considered only in the upper half region of the cross section of the link slab in the reinforced state.

[0096] The self-stress is introduced using the following calculation formula:

[00022]$\{\begin{array}{c}{f}_{\mathrm{sx}}^{\prime }=E_{c,t_{\left(j-i\right)/2}}{\epsilon }_{c,s}+\Delta f_{\mathrm{st}}^{\prime }\mathrm{in}\mathrm{the}\mathrm{reinforced}\mathrm{state}\mathrm{of}\mathrm{the}\mathrm{link}\mathrm{slab}\\ f_{\mathrm{sx}}=f_{s\rho }+\Delta f_{\mathrm{st}}\mathrm{in}\mathrm{the}\mathrm{un}-\mathrm{reinforced}\mathrm{state}\mathrm{of}\mathrm{the}\mathrm{link}\mathrm{slab}\end{array}$ [0097] where f.sub.sx′ is a design self-stress of the link slab in an un-reinforced state, E.sub.c, t.sub.(j−i)/2 is an elastic modulus of the expansive concrete at a moment (j−i)/2, ε.sub.c,s is an expansive deformation of the expansive concrete under constraints of the continuous structure, and equals to a free expansive deformation of the expansive concrete minus an elastic shrinkage deformation and a creep deformation of the expansive concrete, which is represented as ε.sub.c,s=ε.sub.c,0−ε.sub.c,el−ε.sub.c,cr, where ε.sub.c,0 is the free expansive deformation of the expansive concrete, ε.sub.c,el is the elastic shrinkage deformation of the expansive concrete, and ε.sub.c,cr is the creep deformation of the expansive concrete, wherein the free expansive deformation is determined with reference to the test method required in the standard Expansive Agents for Concrete (GB/T 23439-2017), and the elastic shrinkage deformation is measured using a non-contact concrete shrinkage deformation instrument, wherein a cast iron detachable iron mould with a size of 100×100×515 mm may be used, and the pouring sequence is as follows: firstly, ordinary concrete is poured at the two ends of the mould, after the concrete has set and hardened for 28 days, a U-shaped iron target is buried in the instrument, and at the same time, a self-stressed concrete material is poured at the middle part of the mould, the self-stressed concrete material is poured until j, then the expansive deformation of the self-stressed concrete tends to be stable, the limits at the two ends of the iron mould are removed, and a strain value generated by a strain gauge is recorded as the elastic shrinkage of the expansive concrete; the creep deformation is determined according to calculation formulas in the specification CEB-FIP;

[0098] Δf.sub.st′ is a variation of stress caused by a variation of temperature of the plain expansive concrete link slab, Δf.sub.st′=E.sub.c,t(T−T.sub.sj)α.sub.c, where E.sub.c,t is an elastic modulus of the expansive concrete at a moment t,

[00023]$E_{c,t}=\sqrt{\frac{t}{c_1+c_{2}t}}{E}_{c,28},$

T is a temperature of a region where the self-stressed bridge deck link slab is casted, T.sub.sj is a temperature under laboratory conditions, taken as 20° C., t is the age, c.sub.1 and c.sub.1 are constants which may be determined by experimental law fitting, and specifically, may be determined with reference to the static compression elastic modulus test method in the Standard for Test Method of Mechanical Properties on Ordinary Concrete (GB T50081-2002), and obtained by fitting a law of variation of the self-stressed concrete with the age of the elastic modulus, which is a conventional experiment and will not be described in detail herein;

[0099] E.sub.c,28 is an elastic modulus of the expansive concrete at the age of 28 days, and α.sub.c is a linear expansion coefficient of the self-stressed concrete;

[0100] f.sub.sx is a design self-stress of the link slab in a reinforced state, f.sub.sp is a variation of stress caused by a variation of reinforcement ratio of the link slab, f.sub.sp=ρ.sub.xE.sub.sε.sub.sx, where ρ.sub.x is the reinforcement ratio of the link slab, E.sub.s is an elastic modulus of the reinforcement, and ε.sub.sx is a constrained expansive deformation produced by the link slab with different reinforcement ratios, and the constrained expansive deformation varies with the reinforcement ratio in different reinforcement ratio ranges in the following law:

[00024]$\{\begin{array}{c}{\epsilon }_{\mathrm{sx}}=A-100B{\rho }_x+100\mathrm{lnC}{\rho }_x^{2}0.5\%\le \rho \le 1.5\%\\ {\epsilon }_{\mathrm{sx}}={\mathrm{De}}^{-{\mathrm{\alpha \rho }}_x}1.5\%<\rho \end{array}$ [0101] the values of A, B, C and D in the formula may be obtained by experimental law fitting, specifically, by measuring the constrained expansive deformation according to the standard Expansive Agents for Concrete (GB/T 23439-2017), wherein the strain is measured by changing the diameter of the reinforcing bars, i.e., changing the reinforcement ratio of the self-stressed concrete, and as the reinforcement ratio increased, the constrained deformation varies in a binary linear law or exponential law with 1.5% as a boundary, and the values of A, B, C and D in the above formula are obtained by curve fitting of the variation law of the constrained expansive deformation with the reinforcement ratio;

[0102] Δf.sub.st is a variation of stress caused by a variation of temperature of the expansive concrete link slab in the reinforced state,

[00025]$\Delta f_{\mathrm{st}}=\frac{{\rho }_x{E}_s\left(T-T_{\mathrm{sj}}\right)}{1+{\alpha }_E{\rho }_x}\left({\alpha }_c-{\alpha }_s\right),$

where α.sub.s is a linear expansion coefficient of the reinforcement, and α.sub.E is a ratio of the elastic modulus of the reinforcement to the elastic modulus of concrete. [0103] (3) A self-stress is introduced in a case that the self-stressed bridge deck link slab is un-reinforced, a cracking moment M.sub.cr of the plain self-stressed bridge deck link slab is calculated, the cracking moment M.sub.cr and the negative moment M.sub.a are compared, and if M.sub.a≥M.sub.cr, proceed to step (4), otherwise, structural reinforcement are configured as needed, and proceed directly to step (6), wherein the configuration of the structural reinforcement may be performed with reference to the prior art, for example, arranging a reinforcing mesh similar to that used for paving a reinforced bridge deck in the bottom of the link slab along the width direction of the link slab.

[0104] The calculation of the cracking moment M.sub.cr of the plain self-stressed bridge deck link slab includes: [0105] 1) when calculating the cracking moment, the self-stress f.sub.sx′ is introduced according to a uniform compressive pre-stress caused by surrounding constraints of the link slab on a cross section of the link slab, and a horizontal pressure on the cross section of the concrete in an initial state is calculated: Fsx=f.sub.sx′bh; [0106] 2) a decompression moment is calculated: M.sub.0=f.sub.sx′.Math.W.sub.o=⅙f.sub.sx′bh.sup.2; [0107] 3) according to a horizontal force balance equation of concrete stress states:

[00026]$\frac{{\mathrm{bx}}^2}{h-x}{f}_{\mathrm{td}}=\frac{3}{4}b\left(h-x\right)f_{\mathrm{td}},$ [0108] the cracking moment of a concrete link slab is calculated: M.sub.cr,c=0.256f.sub.tdbh.sup.2; and [0109] 4) the cracking moment of the self-stressed concrete link slab is calculated: M.sub.cr=0.256f.sub.tdbh.sup.2+⅙f.sub.sx′bh.sup.2; [0110] where f.sub.td is a design axial tensile strength of concrete; W.sub.o is an inertia resisting moment of concrete; x is a distance between a bottom surface and a neutral axis of the link slab. [0111] (4) A design strength of reinforcement is determined, a reinforcement ratio is selected, and a resisting moment M.sub.u of the self-stressed bridge deck link slab is calculated.

[0112] The determination of the design strength of reinforcement includes: [0113] a) according to a stress-strain relationship of self-stressed concrete and reinforcement, the following physical equation is defined, as shown in FIG. 5:

f.sub.td=E.sub.cε.sub.t0=0.5E.sub.cε.sub.tu

f.sub.y=E.sub.sε−f.sub.ss [0114] where f.sub.td is a design axial tensile strength of concrete; E.sub.c is an elastic modulus of self-stressed concrete; ε.sub.t0 is a tensile strain at yield of self-stressed concrete; ε.sub.tu is an ultimate tensile strain of self-stressed concrete; E.sub.s is the elastic modulus of the reinforcement; ε.sub.s is a strain of the reinforcement under load; f.sub.y is a stress produced when the strain of the reinforcement is ε.sub.s; f.sub.ss is a stress loss caused by stress relaxation of the reinforcement under self-stress, and if f.sub.ss/f.sub.pk≤0.5, f.sub.pk being an ultimate tensile strength of reinforcement, f.sub.ss is 0, and if f.sub.ss/f.sub.pk>0.5, f.sub.ss is determined with reference to the Chinese specification Technical Specifications for Construction of Highway Bridges and Culverts; and [0115] b) assuming that the reinforcement and the concrete are deformed in a coordinated manner, setting an upper limit strength of reinforcement as 40% of the yield strength, namely f.sub.y≤0.4f.sub.sd, calculating the strain of the reinforcement, and when the strain reaches the ultimate tensile strain of concrete ε.sub.tu, determining whether or not σ.sub.s=E.sub.sε.sub.tu is greater than or equal to 0.4f.sub.sd, and if not, namely σ.sub.s=E.sub.sε.sub.tu is less than 0.4f.sub.sd, then taking the design strength of reinforcement as μ times of the yield strength

[00027]$\mu =\frac{E_S{\epsilon }_{\mathrm{tu}}}{f_{\mathrm{sd}}};$ [0116] if so, namely σ.sub.s=E.sub.sε.sub.tu is greater than or equal to 0.4f.sub.sd, taking the design strength of reinforcement as 40% of the yield strength; [0117] in the formula, 40% is an empirical value proposed on the basis that in bending tests of the link slab, under the test conditions, the reinforcement of the link slab endures up to 40% of its yield strength, then the concrete cracks and quits the work. [0118] {circle around (1)} When the design strength of reinforcement is μ times of the yield strength, the reinforcement ratio is taken as ρ, see FIGS. 6-8 (in this case, the self-stress is mainly generated by the constraints of the reinforcement, namely, assuming that the self-stress is uniformly distributed only in the tension region of the cross section of the link slab), and an horizontal force balance equation of the cross section of the link slab is established according to the stress distribution of the cross section of the link slab as follows:

[00028]$\frac{1}{2}\mathrm{bx}.Math.\frac{x}{h-x}.Math.2f_{\mathrm{td}}=\frac{3}{4}b\left(h-x\right)f_{\mathrm{td}}+f_{\mathrm{sx}}b\left(h-x\right)+\mu \left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)$ [0119] where

[00029]$\frac{1}{2}\mathrm{bx}.Math.\frac{x}{h-x}.Math.2f_{\mathrm{td}}$ [0120] is a compressive stress of the self-stressed concrete, ¾b(h−x)f.sub.td is a tensile stress of the self-stressed concrete, f.sub.sxb(h−x) is a self-stress of the self-stressed concrete, and μ(ρf.sub.sdbh−f.sub.ss) is a tensile stress of the reinforcement, wherein when calculating the self-stress of the self-stressed concrete, the f.sub.sx related to the self-stressed concrete is introduced, and when calculating the tensile stress of the reinforcement, the stress loss f.sub.ss caused by constraints of the reinforcement on the expansion of the self-stressed concrete is considered; and

[0121] x is calculated according to a force balance equation, moments produced by four forces with respect to the neutral axis are summed, and a resisting moment of the bearing capacity of the link slab is calculated:

[00030]$M_u=\frac{1}{2}\mu \left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)\left(h-x\right)+f_{\mathrm{sx}}b\frac{{\left(h-x\right)}^2}{2}+\frac{11}{24}{b\left(h-x\right)}^2{f}_{\mathrm{td}}+\frac{2}{3}\left(\frac{{\mathrm{bx}}^3}{h-x}\right)f_{\mathrm{td}};$ [0122] {circle around (2)} when the design strength of reinforcement is 40% of the yield strength, namely the concrete is in an elastic or elastic-plastic stage, a horizontal force balance equation in such condition is established:

[00031]$\frac{1}{2}\mathrm{bx}.Math.\frac{x}{h-x}.Math.2f_{\mathrm{td}}=\frac{3}{4}b\left(h-x\right)f_{\mathrm{td}}+f_{\mathrm{sx}}b\left(h-x\right)+0.4\left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)$ [0123] moments produced by four forces with respect to the neutral axis are summed, and a resisting moment of the bearing capacity of the link slab is calculated:

[00032]$M_u=\frac{1}{2}.Math.0.4.Math.\left(\rho f_{\mathrm{sd}}\mathrm{bh}-f_{\mathrm{ss}}\right)\left(h-x\right)+f_{\mathrm{sx}}b\frac{{\left(h-x\right)}^2}{2}+\frac{11}{24}{b\left(h-x\right)}^2{f}_{\mathrm{td}}+\frac{2}{3}\left(\frac{{\mathrm{bx}}^3}{h-x}\right)f_{\mathrm{td}}.$ [0124] (5) The resisting moment M.sub.u and the negative moment M.sub.a of the link slab are compared, and if M.sub.u≥M.sub.a, it is indicated that design conditions are satisfied, otherwise, the reinforcement ratio is configured and iterative calculation is carried out to obtain a resisting moment M.sub.u satisfying the conditions. [0125] (6) Stress on reinforcement and concrete is analyzed to complete design.

[0126] The stress on reinforcement and concrete is analyzed as follows: [0127] respective tensile and compressive stresses of the reinforcement and the concrete under an actual stress conditions are calculated according to stress-strain distribution of the link slab with a design reinforcement, whether or not the stresses of the reinforcement and the concrete under load exceed stresses bearable by the reinforcement and the concrete is analyzed, and whether or not the link slab cracks is determined; [0128] wherein [0129] the stress bearable by the reinforcement is the yield strength of the reinforcement f.sub.sd, the tensile stress bearable by the concrete is the design axial tensile strength of the self-stressed concrete f.sub.td, and the compressive stress bearable by the concrete is the design axial compressive strength of the self-stressed concrete f.sub.cd (namely, the experimentally measured compressive strength of 28 days); [0130] the tensile stress of the self-stressed concrete (at the upper section of link slab) is: σ.sub.cl=

[00033]$\frac{M_a\left(h-x\right)}{I_{\mathrm{conversion}}}-f_{\mathrm{sx}};$ [0131] the compressive stress of the self-stressed concrete (at the lower section of link slab) is:

[00034]${\sigma }_{\mathrm{cy}}=\frac{M_{a}x}{I_{\mathrm{conversion}}};$ [0132] the tensile stress of the reinforcement is:

[00035]${\sigma }_{\mathrm{sl}}=2{\alpha }_E\frac{M_a\left(h-x\right)}{I_{\mathrm{conversion}}}+f_{\mathrm{ss}};$ [0133] in the formulas, the tensile stress of the self-stressed concrete is a tensile stress of the concrete caused by external load minus a compressive pre-stress of the self-stressed concrete caused by constraints of the reinforcement; the tensile stress of the reinforcement is a tensile stress of concrete caused by external load plus a stress loss caused by constraints of the reinforcement on the expansion of the self-stressed concrete;

[00036]$I_{\mathrm{conversion}}=\frac{\left(1-\rho \right){\mathrm{bh}}^3}{12}+2{\alpha }_E\rho {\mathrm{bh}\left(h-x\right)}^2,{\alpha }_E=\frac{E_S}{E_C}.$

Embodiment 2

[0134] A reinforcement and bearing capacity calculation method for a self-stressed bridge deck link slab is provided. Two kinds of simply supported beam bridges with spans of 25 m and 20 m are selected for calculation. The length of the link slabs are 3.8 m and 3 m, respectively, with the width both being 1 m and the thickness both 0.12 m. HRB335 is selected as the reinforcement and the yield strength is 280 MPa. The tensile strength of the self-stressed concrete is 2.4 MPa, the elastic modulus of the reinforcement is 2×10.sub.5 MPa, the elastic modulus of the self-stressed concrete 3.25×10.sup.4 MPa, and the temperature is 20° C., β=1. In order to provide more reinforcement schemes for the self-stress connection device, three self-stresses, i.e., 2, 3 and 4 MPa in the reinforced state and the un-reinforced state, are used in calculation, and three reinforcement ratios are selected for the calculation of the resisting moment for each self-stress, and the above values are taken into the formula required in the calculation process. The calculation results are shown in Table 1:

TABLE-US-00001 TABLE 1 Calculation of stress of reinforcement for link slab with self-stress Length of Concrete stress Reinforcement link Design Tensile Compressive tensile Span slab M.sub.a self-stress M.sub.cr Reinforcement M.sub.u stress stress stress (m) (m) (KN .Math. m) (MPa) (KN .Math. m) ratio (KN .Math. m) (MPa) (MPa) (MPa) 25 3.8 18.35 2 13.65 1.0% 18.58 2.256725 6.255871 104.7809 1.5% 20.50 1.65657 5.764544 90.00788 2.0% 22.28 1.234803 5.44729 79.62592 3 16.05 1.0% 21.21 1.169686 6.737394 102.6384 1.5% 23.11 0.617039 6.214097 89.0348 2.0% 25.04 0.219799 5.86285 79.25659 4 18.45 0.5% 21.87 0.826008 7.968004 118.794 0.6% 22.22 0.653326 7.772111 114.5434 0.8% 22.95 0.34783 7.432246 107.0235 20 3.0 22.83 2 13.65 2.2% 23.28 1.85591901 6.660224 94.91493 2.4% 24.09 1.70525331 6.560976 91.20624 2.6% 24.92 1.56984397 6.476621 87.87308 3 16.05 1.0% 21.21 2.18768004 8.38227 127.696 1.5% 23.11 1.50010852 7.73121 110.771 2.0% 25.04 1.00588604 7.29421 98.60643 4 18.45 0.5% 21.87 2.00423796 9.91332 147.796 0.6% 22.22 1.78939694 9.66960 142.508 0.8% 22.95 1.40931623 9.24676 133.152

[0135] Assuming that the link slab does not have self-stress, the cracking load of the link slab, the reinforcement ratio, and the resisting moment of the link slab as well as the tensile stress bearable by the reinforcement and concrete are calculated, as shown in Table 2:

TABLE-US-00002 TABLE 2 Calculation of stress of reinforcement for link slab without self-stress Length of Concrete stress Reinforcement link Design Tensile Compressive tensile Span slab M.sub.a self-stress M.sub.cr Reinforcement M.sub.u stress stress stress (m) (m) (KN .Math. m) (MPa) (KN .Math. m) ratio (KN .Math. m) (MPa) (MPa) (MPa) 25 3.8 18.35 0 8.85 1.0% 12.59 4.433797 4.944938 109.1396 1.5% 14.59 3.712849 4.596399 91.3932 2.0% 16.68 3.236759 4.404616 79.67407 20 3.0 22.83 2.2% 12.59 3.84270688 5.416828 94.58971 2.4% 14.59 3.68041171 5.367927 90.59475 2.6% 16.68 3.53625891 5.328397 87.04637

[0136] It can be seen from Table 1 and Table 2 that, under the same conditions, as compared with the link slab without self-stress, the link slab with self-stress has a larger cracking moment M.sub.cr and a larger resisting moment M.sub.u. Besides, the larger the self-stress produced by the self-stressed concrete is, the smaller the required reinforcement ratio is, and also, the data clearly shows that the larger the self-stress value is, the larger the cracking moment is, therefore, the self-stress reinforcement design method is of great significance for practical engineering applications: (1) the reinforcement ratio can be reduced; (2) the cracking load is increased; (3) when the bending moment of the link slab under external load is small, the requirements of non-cracking can be met by the self-stress of the concrete without reinforcement, which provides a numerical reference for this situation.

[0137] While the foregoing is directed to the preferred embodiments of the present disclosure, it will be understood by those skilled in the art that numerous modifications and adaptations may be made without departing from the principles of the disclosure, and such modifications and adaptations are intended to be within the scope of the disclosure.