SLS design (crack control) of I-shaped, T-shaped, box-shaped reinf. concrete section

Concrete characteristic strength

f_ck

MPa

e.g. 30 MPa for concrete class C30/37. For a list of concrete classes see Table of Concrete Design Properties

Normalized maximum compressive stress permitted in the concrete

σ_c,lim/f_ck

A value of 1.0 will yield the most economic reinforcement. Lower values may be provided if concrete stress limitation is desired. According to EN 1992-1-1 §7.2(2) to avoid longitudinal cracks the compressive stress in the concrete should be limited to 0.6f_ck for the characteristic SLS combination for adverse environment (exposure classes XD, XF, XS) and in the absence of other measures. According to EN 1992-1-1 §7.2(3) the effects of non-linear creep should be considered when the compressive stress in the concrete exceeds 0.45f_ck for the quasi-permanent SLS combination

Type of stress-strain law for concrete

The parabolic stress-strain law may be used for SLS (no partial safety factors) according to EN1992-1-1 §3.1.7(1) Figure 3.3. The linear stress-strain law (without tension) is a good approximation and it can also take into account an effective modulus of elasticity e.g. due to the effects of creep or aggregate type.

Modification factor for modulus of elasticity of concrete

E_c,eff/E_cm

A value of 1.0 corresponds to the value of the secant modulus of elasticity E_cm as defined in EN1992-1-1 Table 3.1. To take into account the long-term effects of creep a value of 1 / [1 + φ(∞, t₀)] can be provided, as specified in EN 1992-1-1 §7.4.3(5). To take into account more refined values of the modulus of elasticity based on the aggregate type an appropriate value can be provided, e.g. as specified in EN 1992-1-1 §3.1.3(2) and the National Annex.

Steel characteristic yield strength

f_yk

MPa

Maximum tensile stress permitted in the reinforcement

σ_s,lim

MPa

According to EN 1992-1-1 §7.2(5) tensile stress in the reinforcement should be limited to 0.8f_yk for the characteristic SLS combination.

Height of cross-section

h

m

Width of web (or sum of widths of webs)

b_w

m

Width of top flange

b_f,top

m

Thickness of top flange

t_f,top

m

Width of bottom flange

b_f,bot

m

Thickness of bottom flange

t_f,bot

m

Number of bars of bottom reinforcement layer 1

n_bars,1

Enter 0 to disable the bottom reinforcement layer. Non-integer values are handled by suitable modification of bar cross-sectional area.

Diameter of bars of bottom reinforcement layer 1

Φ₁

mm

Distance from centroid of bottom reinforcement layer 1 to bottom concrete edge

c'₁

m

Number of bars of top reinforcement layer 2

n_bars,2

Enter 0 to disable the top reinforcement layer. Non-integer values are handled by suitable modification of bar cross-sectional area.

Diameter of bars of top reinforcement layer 2

Φ₂

mm

Distance from centroid of top reinforcement layer 2 to top concrete edge

c'₂

m

Distance from bar centroid of top reinforcement layer to concrete edge

Number of bars of side reinforcement layer 3 per side

n_bars,3

Enter 0 to disable the side reinforcement layer. Non-integer values are handled by suitable modification of bar cross-sectional area.

Diameter of bars of side reinforcement layer 3

Φ₃

mm

Distance from centroid of side reinforcement layer 3 to side concrete edge

c'₃

m

Distance from centroid of side reinforcement layer to concrete edge

Check crack control for side reinforcement

Crack control verification can be deactivated for side reinforcement if it is fulfilled by other means e.g. EN 1992-1-1 §7.3.3(3)

Type of analysis

Design value of the bending moment - SLS combination (positive when tension at bottom side)

M_Ed

kNm

The design value of the bending moment at the appropriate SLS combination for which the required reinforcement will be determined

Design value of the axial force - SLS combination (compression negative)

N_Ed

kN

The design value of the axial force at the appropriate SLS combination for which the maximum bending moment resistance of the cross-section will be calculated (typically the quasi-permanent combination for reinforced concrete, see EN1992-1-1 §7.3.1).

Variable reinforcement layers to be modified

The specified layers will be modified proportionally by multiplication by the same factor. The rest of the layers will remain unchanged.

Factor dependent on the duration of the load

k_t

According to EN1992-1-1 §7.3.4(2). Typically the crack control verification of reinforced concrete is carried out for the quasi-permanent combination therefore a value of k_t = 0.4 for long-term loading is applicable. For short-term loading a value of k_t = 0.6 is applicable. Intermediate values are possible.

Limiting value for the calculated crack width

w_max

mm

According to the National Annex to EN1992-1-1 §7.3.1(5). Typically for crack control verification of reinforced concrete a value of w_max = 0.3 mm is applicable.

Concrete cover to tensile reinforcement surface

c

mm

Crack control verification is strongly affected by the concrete cover c (distance between the surface of longitudinal reinforcement closest to the nearest concrete surface). Larger values of c produce more unfavorable results.

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