Abstracts

1 INTRODUCTION

The design of flat slabs is often controlled by the punching shear strength of the slab-column connections. Slab-column connections are usually subjected to unbalanced moments that yield additional shear stresses and reduce the punching shear capacity.

Eurocode 2 [¹1 Comité Européen de Normalisation, Eurocode 2 - Design of concrete structures – Part 1-1: General rules and rules for Buildings, Stockholm, Sweden: Comité Européen de Normalisation, 2004.] and the Brazilian code NBR 6118 [²2 Associação Brasileira de Normas Técnicas, Design of Concrete Structures – Procedures, NBR 6118, 2014.] adopt the Model Code 90 [³3 Comité Euro-International du Béton, Model Code 1990 for structures. London, England: Comité Euro-International du Béton, 1993.] punching shear design model with modifications. In this work, these codes are referenced by the abbreviations EC2, NBR6118, and MC90, respectively. The MC90 model compares acting stresses with resisting stresses in control perimeters.

Shear forces due to normal forces are assumed to be uniformly distributed along control perimeters or reduced control perimeters. Shear forces distributed due to unbalanced moments are considered fully plastic in both positive and negative directions. The positive and negative parts of the perimeter may show symmetry, but they are often asymmetrical. Plastic asymmetrical bending diagrams require nonlinear solutions.

This paper proposes a numerical procedure for the determination of asymmetrical plastic shear diagrams in arbitrary control perimeters. The procedure is tested together with the empirical equations set forth in MC90, EC2, and NBR6118. The results are compared with experimental data from the literature.

2 SELECTED RECOMMENDATIONS FROM THE CODES

Research that influenced the design of the MC90 model is discussed by Regan [⁴4 P. E. Regan, Behavior of Reinforced Concrete Flat Slabs. Report 89. London, England: CIRIA, 1981.] and Regan and Braestrup [⁵5 P. E. Regan and M. W. Braestrup, Punching Shear in Reinforced Concrete (Bulletin d’Information, 168). London, England: Comité Euro-International du Béton, Jan., 1985.]. The ACI 318-19 [⁶6 American Concrete Institute, Building Code Requirements for Structural Concrete and Commentary, ACI 318R-19, 2019.] and Model Code 2010 [⁷7 Fédération Internationale du Béton, fib Model Code for Concrete Structures, Model Code 2010. Lausanne, Switzerland: Fédération Internationale du Béton, 2012.] recommendations are not discussed here. ACI 318-19 adopts the linear elastic hypothesis proposed by di Stasio and van Buren [⁸8 J. di Stasio and M. P. van Buren, "Transfer of bending moment between flat plate floor and column," ACI J. Proc., vol. 57, pp. 299–314, Jan 1960, http://dx.doi.org/10.14359/8022.
http://dx.doi.org/10.14359/8022... ]. Model Code 2010 verifies plastic distributions based on the Critical Shear Crack Theory (Muttoni [⁹9 A. Muttoni, "Punching shear strength of reinforced concrete slabs without transverse reinforcement," ACI Struct. J., vol. 105, no. 4, pp. 440–450, Jul 2008, http://dx.doi.org/10.14359/19858.
http://dx.doi.org/10.14359/19858... ] and Ruiz and Muttoni [¹⁰10 M. F. Ruiz and A. Muttoni, "Applications of critical shear crack theory to punching of reinforced concrete slabs with transverse reinforcement," ACI Struct. J., vol. 106, no. 4, pp. 485–494, Jul. 2009, http://dx.doi.org/10.14359/56614.
http://dx.doi.org/10.14359/56614... ]).

MC90, EC2, and NBR6118 verify the capacity of slabs without transverse reinforcement at Perimeter 1. Perimeter 1 is at distance $2d$ from the column face, where $d$ is the effective depth of the slab. Considering elements without shear reinforcement, the punching strength of slabs at Perimeter 1 corresponds to the shear strengths of the linear members (FIB Bulletin 2 [¹¹11 Fédération Internationale du Béton, Textbook on Behaviour, Design and Performance, vol. 2: Basis of Design (Bulletin d’Information, 2). Lausanne, Switzerland: Fédération Internationale du Béton, 1999.]). The three codes present equivalent expressions for design shear stresses ${\tau }_{Rd}$, whose parameters are determined using the respective partial safety factors for concrete ${\gamma }_c$.

Compressive stresses in concrete struts are verified at Perimeter 0, which is adjacent to the column. Although the ${\tau }_{Rd}$ expressions are similar at Perimeter 0, MC90, EC2, and NBR6118 reduce the diagonal compressive capacity by different factors.

Perimeter $n$ is tested when transverse reinforcement is required. The distance between this perimeter and the outer reinforcement contour is $kd$. MC90 and NBR6118 use $k=2$, while EC2 uses $k=1.5$. The three codes define maximum stresses for transverse reinforcement but use different approaches.

The differences between the codes are more significant in the control perimeters submitted to bending. The plastic diagrams of internal columns subjected to biaxial bending are asymmetrical. This issue is only addressed in EC2, which indicates an empirical solution. MC90 and EC2 ignore moments with internal eccentricity in edge and corner columns. NBR6118 partially includes internal moments of edge and corner columns when their eccentricities are greater than the eccentricities between the columns and the reduced control perimeters.

3 PUNCHING SHEAR DESIGN WITH UNBALANCED MOMENTS

Any evaluation of shear forces along a control perimeter must consider that the bending and torsional moments resist part of the unbalanced moment. The $K$ factor is defined as the fraction of the unbalanced moment that is resisted by shear forces.

The moments transferred to the slab by bending and shear are experimentally investigated by Hanson and Hanson [¹²12 N. W. Hanson and J. N. Hanson, "Shear and moment transfer between concrete slabs and columns", J. of the PCA Rsrch. and Devel. Lab., vol. 10, no. 1, pp. 2–16, Jan. 1968.] on square columns. The ratios of unbalanced moments resisted by shear are analytically discussed by Mast [¹³13 P. E. Mast, "Stresses in flat plates near columns," ACI J. Proc., vol. 67, no. 10, pp. 761–768, Oct. 1970, http://dx.doi.org/10.14359/7306.
http://dx.doi.org/10.14359/7306... ] for internal columns (Figure 1). The corresponding $K$ factor is estimated by the elastic solution of a plate subjected to a concentrated moment. The plate is simply supported in the main direction and is infinite in the other direction (Girkmann [¹⁴14 K. Girkmann, Flaechentragwerke : Einführung in Die Elastostatik der Scheiben, Platten, Schalen und Faltwerke, 5th ed. Wien, Austria, Springer-Verlag, 1959.]). The $K$ factor can be defined as a function of the control perimeter shape in the region close to the column.

Figure 1
Unbalanced moment transfer in slab-column connections

Design $K$ values indicated in MC90 are compared with Mast’s [¹³13 P. E. Mast, "Stresses in flat plates near columns," ACI J. Proc., vol. 67, no. 10, pp. 761–768, Oct. 1970, http://dx.doi.org/10.14359/7306.
http://dx.doi.org/10.14359/7306... ] approximate elastic solution (Figure 1). The analytical values assume that lengths $a$ and $b$ vary between $L/20$ and $L/5$, where $L$ is the span between the columns. Figure 1 also shows the elastic distribution of shear forces along a square perimeter, where $a=b=L/10$.

Shear force distribution in reinforced concrete flat slabs has also been studied by nonlinear finite element analyses. Shu et al. [¹⁵15 J. Shu, B. Belleti, A. Muttoni, M. Scolari, and M. Plos, "Internal force distribution in RC slabs subjected to punching shear," Eng. Struct., vol. 153, pp. 766–781, Dec 2017, http://dx.doi.org/10.1016/j.engstruct.2017.10.005.
http://dx.doi.org/10.1016/j.engstruct.20... ] investigate internal columns without unbalanced moments in flat slabs without shear reinforcement. The shear force distributions along the control perimeters are determined by shell and solid nonlinear finite element models. The results show that reinforcement arrangement, cracking and nonlinear material behavior influence the shear force distribution. Laguta [¹⁶16 M. Laguta, "Effect of unbalanced moment on punching shear strength of slab- column joints", M.S. thesis, Civil and Env. Eng., Univ. Waterloo, Ontario, 2020. [Online]. Available: https://uwspace.uwaterloo.ca/handle/10012/15931?show=full
https://uwspace.uwaterloo.ca/handle/1001... ] uses a concrete damaged plasticity material model to describe the nonlinear behavior of the concrete and present a typical shear stress distribution at a control perimeter under combined vertical load and unbalanced moment.

Normal force and bending moment are considered separately in the MC90 design model and produce distinct plastic shear force diagrams per unit length (Figure 2). The plastic shear forces related to normal force $F$ and bending moment $M$ are respectively denoted by $v_F$ and $v_M$.

Figure 2
Coordinate system, applied forces and moments, and distributed shear forces

MC90 defines an effective normal force $F_{ef}$, including the effect of unbalanced moment. The plastic diagrams for normal force $F$ and bending moment $M$ determine the effective force $F_{ef}$. EC2 uses the same methodology, presented by coefficient $\beta$, such that $F_{ef}=\beta F$.

$F_{ef}^j$ is here defined as the effective force that is calculated on Perimeter $j$. The following expressions apply:

where $W_p^j$ is the plastic modulus and $u^j$ is the developed length of Perimeter $j$. Reduced lengths $u^{*j}$ are defined for edge and corner columns. Reduced lengths $u^{*j}$ correspond to developed lengths $u^j$ in internal columns.

The combined shear force per unit length $v_{MF}^j$ is expressed by

The effective force $F_{ef}^j$ on Perimeter $j$ is given by

4 PLASTIC MODULUS FOR ASYMMETRICAL BENDING

A numerical procedure is used to determine the plastic shear diagram and the plastic flexural modulus of an arbitrary perimeter, which is subjected to a bending moment $M$ about an oblique axis.

$M_x$ and $M_y$ are the vector components of bending moment $M$ about the $x-$ and $y-$axes, respectively (Figure 3).

Figure 3
Rotated coordinate system associated with the principal moments

4.1 Moments in the principal coordinate system

Figure 3 presents the principal coordinate system $\bar{x}\bar{y}$. The system is rotated from the $xy$ coordinate system by an angle $\alpha$, which is defined by

Considering $\bar{x}=x\mathit{cos}\alpha +y\mathit{sin}\alpha$ and $\bar{y}=-x\mathit{sin}\alpha +y\mathit{cos}\alpha$, the equilibrium conditions of the shear forces per unit length $v$ along the perimeter $U$ yield

where $M_{\bar{x}}$ and $M_{\bar{y}}$ are the moments about the $\bar{x}-$ and $\bar{y}-$axes (Figure 3).

4.2 Distribution of shear forces per unit length

Shear forces $v=-v_M$ and $v=+v_M$ (Figure 2) are considered uniformly distributed along perimeter lengths $U^{-}$ and $U^{+}$, respectively. The equilibrium conditions in the $z-$direction and about the $x-$ and $y-$axes lead to the following equations:

Collecting like terms in Equations 7 to 9 yields

where the plastic flexural moduli $W_{p\bar{x}}$ and $W_{p\bar{y}}$ are

A numerical algorithm establishes perimeter lengths $U^{-}$ and $U^{+}$.

4.3 Discretization and parametrization of the control perimeter

The perimeter is divided into linear and arc segments for the application of the numerical procedure.

The developed length of the control perimeter is defined as $u$. The numerical procedure demands that all segments have lengths less than the semi-perimeter $u/2$. This condition is satisfied by the division into segments shown in Figure 4.

Figure 4
Discretization of control perimeters into segments $S_i$

The points that divide the segments are numbered from $1$ to $N$. The control perimeter is parameterized according to the developed length $s$, where $s_1=0$ at start point 1 and $s_N=u$ at endpoint $N$ (Figure 5).

Figure 5
Parameter $s$ and unit shear force distribution along the control perimeter

This parameterization is valid for open and closed perimeters. Points $1$ and $N$ are distinct for open perimeters but coincident for closed perimeters.

Figure 5 also presents a flat diagram of unit shear forces per unit length. The longitudinal axis indicates parameter $s$, which is the developed length from the origin $\left(s_1=0\right)$. The unit shear forces change signs at points $A$ and $B$. The perimeter length of positive shear forces $U^{+}$ is defined between points $A$ and $B$. The perimeter length of negative shear forces $U^{-}$ is defined in intervals $1-A$ and $B-N$.

Equation 10 shows that the developed lengths of the perimeter lengths $U^{-}$ and $U^{+}$ are both equal to the semi-perimeter $u/2$.

4.4 Plastic flexural modulus

The parameters $s$ of points $A$ and $B$ are defined as $s_A$ and $s_B$, respectively. Equation 10 is automatically respected by adopting the following

A parameter $s_A$ yields $s_B$ by Equation 14. Perimeter lengths $U^{-}$ and $U^{+}$ are defined in Figure 5. The plastic flexural moduli $W_{p\bar{x}}\left(s_A\right)$ and $W_{p\bar{y}}\left(s_A\right)$are determined by Equations 11 and 12, respectively.

The algorithm searches for a parameter $s_A^{*}$ that yields $W_{p\bar{y}}\left(s_A^{*}\right)\simeq 0$. The solution $s_A^{*}$ yields a unit diagram proportional to the shear force diagram that satisfies Equations 5 and 6.

The plastic flexural modulus $W_p$ and the shear force per unit length $v_M$ are given by

where $v_M$ is always positive.

If $\bar{y}$ coordinates are always negative in $U^{-}$ and positive in $U^{+}$, or always positive in $U^{-}$ and negative in $U^{+}$, Equations 11 and 15 yield

Equation 17 cannot be used in the general case, but it is valid for symmetrical perimeters about the $\bar{x}-$ axis. It is applicable in specific cases, such as edge columns subjected to moments $M_{\bar{x}}=M_x$ (Figure 4).

4.5 Partial integration of a same-sign length of a segment

Changes in the sign of unit shear forces can occur in linear and arc segments. Equations 11 and 12 yield the plastic flexural moduli $W_{p\bar{x}}$ and $W_{p\bar{y}}$ by integrating lengths with shear forces of the same sign.

A segment’s start and end points are defined as $I$ and $J$, respectively (Figure 6). Points $P$ and $Q$ determine a length with positive shear forces.

Figure 6
Partial integration between points $P$ and $Q$

The variables associated with points $P$, $Q$, $I$, and $J$ that are known are the parameters $s_I$, $s_J$, $s_P$, and $s_Q$ and the coordinates ${\bar{x}}_I$, ${\bar{y}}_I$, ${\bar{x}}_J$, and ${\bar{y}}_J$. The dimensionless factors ${\zeta }_{GI}$ and ${\zeta }_{GJ}$ of a generic point $G$ on the segment are defined by

In the case of linear segments, $H$ is defined as the barycenter of $PQ$. The parameter $s_H$ and coordinates ${\bar{x}}_H$ and ${\bar{y}}_H$ are equal to

where $W_{p\bar{x}}^{PQ}$ and $W_{p\bar{y}}^{PQ}$ are the contributions of $PQ$ to the plastic moduli $W_{p\bar{x}}$ and $W_{p\bar{y}}$. In linear segments, they are expressed by

where $\Delta s$ is the length between $P$ and $Q$.

In arc segments, the following variables are also considered: angles ${\alpha }_I$ and ${\alpha }_J$ at points $I$ and $J$, coordinates $x_C$ and $y_C$ of the center, and radius $r$. Angles ${\alpha }_P$ and ${\alpha }_Q$ are interpolated by

The following expressions yield the contributions of $PQ$ to the plastic moduli $W_{p\bar{x}}$ and $W_{p\bar{y}}$ in arc segments:

The developed length $\Delta s$ between $P$ and $Q$ is

4.6 Full segment integration

Unit shear forces on lengths $PQ$ (Figure 6) can be positive or negative. Figure 7 discusses the positive and negative shear forces that should be considered during the complete integration of a segment $IJ$.

Figure 7
Unit shear force along the control perimeter

Each segment cannot simultaneously contain points $A$ and $B$, since all segments have a developed length less than the semi-perimeter $u/2$. The discretization into segments shown in Figure 4 meets this requirement.

Parameters $s_A$ and $s_B$ define segments $S_A$ and $S_B$, which respectively contain points $A$ and $B$.

Table 1 defines the coordinates $s_P$ and $s_Q$ of each segment $S$ integration step, according to its location. Equations 21 and 24 are established for a positive unit shear force. The effective signs of unit shear forces will be considered as indicated in the table.

5 IMPLEMENTATION AND EXAMPLES

The previous steps define an iteration that yields the plastic flexural moduli $W_{p\bar{x}}\left(s_A\right)$ and $W_{p\bar{y}}\left(s_A\right)$ as a parameter function $s_A$. The parameter $s_A^{*}$ associated with $W_{p\bar{y}}\left(s_A^{*}\right)\cong 0$ gives the principal plastic modulus $W_p=\left|W_{p\bar{x}}\left(s_A^{*}\right)\right|$, which depends on the direction of the applied bending moment $M$. The solution $s_A^{*}$ is searched for in the interval $0\le s_A<\frac{u}{2}$.

As the computational cost of the procedure is low, the solution can be investigated by sequentially examining many values in the range. This process can be optimized by dividing the original interval into $m$ subintervals. The solution subinterval is identified by the change in the sign of $W_{p\bar{x}}$ at its endpoints, but the endpoints themselves should be previously verified as possible solutions. The solution subinterval is iteratively divided into $m$ subintervals until the required tolerance is reached. This work uses $m=20$.

Figure 8 shows examples of internal, reentrant corner, edge, and corner columns. All columns are subjected to unbalanced moments about an oblique $\bar{x}-$axis, which is rotated 60 degrees from the $x-$axis, in the counterclockwise direction. Perimeter 1 unit shear diagrams are shown.

Figure 8
Examples: asymmetrical diagrams of unit shear forces

The sections of all the columns are 0.60 x 0.30 m, and all the slabs have 0.15 m effective depth.

The signs of the shear forces change in the arc and linear segments. The shear force diagrams depend on the direction of the acting bending moment and do not show symmetry.

6 COMPARISON WITH EXPERIMENTS IN THE LITERATURE

Experimental results in the literature are analyzed using MC90, EC2, and NBR6118 together with the proposed procedure.

Asymmetrical bending results can be compared with values usually accepted by these codes as the dataset also includes tests that yield symmetrical diagrams in bending.

The formulas from the codes are used with ${\gamma }_f={\gamma }_c={\gamma }_s=1$, where ${\gamma }_f$ is the partial factor for actions. Parameters ${\gamma }_c$ and ${\gamma }_s$ are the partial factors for concrete and reinforcing steel, respectively.

Shear reinforcement arrangements are always distributed uniformly in the literature tests discussed in this work. Perimeter $n$ may be discontinuous since perimeter lengths with distances greater than $d$ to the nearest transverse reinforcement will not be considered. For uniformly distributed shear reinforcement, the effective shear force $v_{MF,ef}$ is estimated by the following equation:

The combined shear force $v_{MF}$ for continuous perimeters is determined according to each code. The average spacing between transverse bars in the outer reinforcement contour is $s_{avg}$. The maximum spacing $s_{max}$is defined as $2d$.

Although the procedures in EC2 and NBR6118 are based on MC90, the differences between them significantly affect the results. The following code criteria are discussed in this work:

1. Size effect ($\xi$)

In MC90, EC2, and NBR6118, design shear stress ${\tau }_{Rd}$ depends on the size effect parameter $\xi =1+\sqrt{\frac{0.2\mathrm{m}}{d}}$. EC2 also assumes $\xi \le 2$.

1. Reinforcement ratio for longitudinal reinforcement ($\rho$)

Design shear stress ${\tau }_{Rd}$ is also a function of the longitudinal reinforcement ratio $\rho =\sqrt{{\rho }_x{\rho }_y}$ in MC90, EC2, and NBR6118. Parameters ${\rho }_x$ and ${\rho }_y$ are the ratios in the $x-$ and $y-$directions, respectively. EC2 also assumes $\rho \le 0.02$.

1. Effective design yield stress of shear reinforcement ($f_{ywd,ef}$)

All the codes limit the effective design yield stress of shear reinforcement $f_{ywd,ef}$. MC90 adopts $f_{ywd,ef}\le 300\text{MPa}$. In EC2, the maximum value depends on the effective depth $d$ of the slab. NBR6118 defines different limits for connectors and stirrups depending on total depth $h$. In this work, the NBR6118 formulation is adapted for effective depth $d=h-0.03\mathrm{m}$.

1. Distance between Perimeter n and the outer transverse reinforcement contour ($kd$)

MC90 and NBR6118 establish the distance $kd=2d$ between Perimeter $n$ and the outer transverse reinforcement contour. EC2 assumes $kd=1.5d$.

1. Edge and corner column moments with internal eccentricity ($M^{\mathrm{*}}$)

MC90 and EC2 do not consider moments with internal eccentricity in edge and corner columns. NBR6118 partially includes internal moments that are larger than $M^{*}$, which are the moments that can be resisted by eccentricities between columns and reduced control perimeters.

1. Perimeter 0 length on edge and corner columns ($u^{0\mathrm{*}}$)

In edge and corner column connections, MC90 and EC2 assume a reduced length for Perimeter 0, which is here denoted as $u^{0*}$. NBR6118 does not assume a reduced length for Perimeter 0.

1. Effective normal force due to unbalanced moments ($F_{ef}$)

$F_{ef}^j$ is defined as the effective normal force that is calculated on a control Perimeter $j$. MC90 uses $F_{ef}^1$ and $F_{ef}^n$ on Perimeters 1 and $n$, respectively, and reuses $F_{ef}^1$ on Perimeter 0. EC2 only calculates $F_{ef}^1$, which is used as the effective normal force on all perimeters. Effective forces are not discussed in NBR6118.

1. Concrete strength reduction factor in diagonal compression (${\alpha }_{\theta }$)

The concrete stress in diagonal compression is limited to ${\alpha }_{\theta }{\alpha }_V{f}_{cd}$ at Perimeter 0, where $f_{cd}$ is the concrete design strength and ${\alpha }_V=\left(1-\frac{f_{ck}}{250\text{MPa}}\right)$. The reduction factor ${\alpha }_{\theta }$ is given as 0.30, 0.24, and 0.27 in MC90, EC2, and NBR6118, respectively.

Ten combinations (C1 to C10) of eight criteria from the codes are presented in Table 2. Combinations C1 to C3 correspond to MC90, EC2, and NBR6118, respectively. C4 to C10 investigate the response of different criteria a to h in EC2 and NBR6118.

Ninety-four experiments of slab-column connections subjected to punching shear were compiled from the literature and their experimental capacity was compared with the theoretical capacity given by the combinations in Table 2. The dataset contains internal, reentrant corner, edge, and corner columns subjected to normal forces, with and without unbalanced moments. The tests include slabs without shear reinforcement. Transverse reinforcement is provided by shear studs.

Tables 3 to 11 present the results of all the experiments retrieved from the literature for the C5 combination. The sides of the columns are $c_x$ and $c_y$, respectively, in the $x-$ and $y-$directions. Characteristic strength $f_{ck}$ is substituted in the code equations by the as-tested compressive strength of concrete. Transverse reinforcement is arranged in $n_p$ contours and $n_r$ rails. $A_{sw}^{\varphi }$ is one bar area. The distance from the first reinforcement contour to the column and the distance between the reinforcement contours are denoted as $s_0$ and $s_r$, respectively.

The slab capacity is verified at Perimeters 0, 1, and $n$. The critical control perimeters are shown in Tables 3 to 11. The prediction ratio $\psi$ is the ratio between the experimental and estimated capacities, considering ${\gamma }_f={\gamma }_c={\gamma }_s=1$.

A brittle failure of a slab-column connection can cause the progressive collapse of the structure. Table 2 shows the percentages of experiments with $\psi \ge 0.95$ in each combination, which indicates the reliability of the combination. Table 2 also presents the mean and the minimum $\psi$ ratios of each combination, which are denoted as ${\psi }_{mean}$ and ${\psi }_{min}$, respectively.

C1, C2, and C3 correspond to MC90, EC2, and NBR6118, respectively. Among them, C2 (EC2) gives the highest number of predictions with $\psi \ge 0.95$ (94%). C2 yields inadequate predictions in some cases. The minimum C2 prediction ratio $\left({\psi }_{min}=0.18\right)$ is associated with the corner column connection C_C_4 in Stamenkovic and Chapman [¹⁸18 A. Stamenkovic and J. C. Chapman, "Local strength at column heads in flat slabs subjected to a combined vertical and horizontal loading," Proc. Inst. Civ. Eng., vol. 57, pp. 205–232, Jun. 1974, http://dx.doi.org/10.1680/iicep.1974.4054.
http://dx.doi.org/10.1680/iicep.1974.405... ], which is subjected to unbalanced moment. The normal force is relatively small.

Combination C4 corresponds to EC2 with the moment approach proposed by NBR6118 for edge and corner columns (criteria e). Combinations C5 to C10 discuss the effect of replacing other criteria in C4.

Combinations C4, C5, and C8 yield $\psi \ge 0.95$ for 99% of the dataset. The average and minimum prediction ratios are ${\psi }_{mean}=1.42$ and ${\psi }_{min}=0.92$, respectively. The minimum prediction ratio is associated with the specimen L4 in Trautwein et al. [²⁵25 L. M. Trautwein, R. B. Gomes and G. S. S. A. Melo, "Puncionamento em lajes planas de concreto armado com armadura de cisalhamento interna", vol. 7, no. 1, pp. 38-49, Nov., 2013, http://dx.doi.org/10.5216/reec.v7i1.24333.
http://dx.doi.org/10.5216/reec.v7i1.2433... ], which fails at Perimeter 0 by diagonal compression in concrete. The moment criterion proposed by NBR6118 yields good capacity predictions for edge and corner column connections with internal eccentricities.

Combinations C4 and C5 show that the criteria proposed by NBR6118 and EC2 for effective yield stress $f_{ywd,ef}$ provide similar results.

Combination C8 investigates the criterion f from NBR 6118, by which the effective length of Perimeter 0 is not reduced in edge and corner columns. New studies are needed as the current dataset does not contain failures due to diagonal compressive stresses in edge and corner column connections.

Combinations C6, C7, and C10 show that criteria a ($\xi$), b ($\rho$), d ($kd$), and h (${\alpha }_{\theta }$) from NBR6118 do not contribute to C5 predictions.

Combinations C5 and C9 apply the effective forces $F_{ef}^1$ and $F_{ef}^n$ at Perimeter $n$, as recommended by EC2 and MC90, respectively. They both yield similar predictions, but this conclusion is limited to the uniformly distributed reinforcement arrangements of the dataset. Non-uniform reinforcement distributions can change the effective $F_{ef}^n$ forces. Cross arrangements of shear reinforcement demand further investigation.

The dataset contains 16 reentrant corner columns, five corner columns, and 18 edge columns yielding asymmetrical plastic shear diagrams. Row “C5-Asym.” of Table 2 discusses the results of combination C5 for the asymmetrical subset. Relations ${\psi }_{mean}=1.66$ and ${\psi }_{min}=1.06$ are considered adequate and compatible with the results of the complete set.

7 CONCLUSIONS

A numerical procedure yields plastic diagrams of shear forces in arbitrary control perimeters subjected to asymmetrical bending. Examples of internal, reentrant corner, edge, and corner columns are subjected to unbalanced moments about an axis oblique to the principal axes. The proposed procedure is fast, robust, and accurate.

Experimental results in the literature are compared to the MC90, EC2, and NBR6118 design methods, which are applied together with the proposed procedure.

Although the recommendations in EC2 and NBR6118 are based on MC90, they contain some differences, which are discussed as they significantly affect the results.

EC2 performed better than the other two codes. A similar conclusion is reported by Ferreira et al. [²¹21 M. P. Ferreira, M. H. Oliveira, and G. S. S. A. Melo, "Tests on the punching resistance of flat slabs with unbalanced moments," Eng. Struct., vol. 196, no. July, 2019, http://dx.doi.org/10.1016/j.engstruct.2019.109311.
http://dx.doi.org/10.1016/j.engstruct.20... ] when comparing ACI, EC2 and Model Code 2010 [⁷7 Fédération Internationale du Béton, fib Model Code for Concrete Structures, Model Code 2010. Lausanne, Switzerland: Fédération Internationale du Béton, 2012.]. However, some results of EC2 were not considered satisfactory, because this code disregards the moments of corner and edge columns with internal eccentricities.

NBR6118 considers the portions of the unbalanced moments that exceed the moments that can be resisted by the eccentricities between columns and reduced control perimeters of corner and edge columns. The best performance is obtained by combining EC2 with the NBR6118 moment criterion. Ninety-nine percent of the dataset yields prediction to experimental results ratios greater than 0.95. All prediction to experimental rates are greater than 0.92.

The prediction to experimental ratios of cases with symmetrical and asymmetrical plastic diagrams are compatible.

Asymmetrical shear diagrams are found not only in edge and corner column connections but also in internal column connections. The proposed procedure considers the asymmetrical plastic diagrams that usually occur in all column connections due to biaxial bending.

Connections of edge and corner columns, critical at Perimeter 0, and plastic shear diagrams, discontinuous due to cross-arranged reinforcement, are themes for future studies.

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