Rib in the slab

In SCIA Engineer, aplate rib is a particular type of beam, which has a continuous connection to a plate along the entire length of the beam. The beam may be eccentric, i.e. placed above or below the plate.

For analysis, the beam is considered as a distinct entity which fully collaborates with the plate. As a result, the analysis produces beam results in the plate rib (internal forces N, Vy, Vz, Mx, My, Mz) and plate results in the plate (internal forces mx, my, mxy, vx, vy, nx, ny, nxy).

For results output and checks, the possibility exists to define the effective width beff, which enables two things:

Separate values of effective width are used for the calculation of internal forces and for checks. They can be defined manually or computed automatically. The latter is the default setting.

The value of effective width does not affect the behaviour of the model, as the plate is analysed as a finite element plate, not as a part of the cross-section of the beam. The effective width is considered only during post-processing, when integrating the results obtained in the plate and when calculating the strength of the cross-section during the checks.

Composite beams are a particular case: the composite analysis model allows to calculate consider the effective width of the beam in the calculation of the stiffness of the beams.

Properties of a plate rib

Name

Defines the name of the rib.

Type

Informs about the type of the entity.

Analysis model

This parameter defines how the rib will be considered in the analysis.

Standard = the rib of a standard cross-section

Cellular beam = the rib is made of a cellular beam

"special cellular beam parameters"

If the cellular beam is selected, the dialogue allows for input of additional parameters defining the position of posts in the beam.

Cross-section

Defines the cross-section of the rib.

Alignment

Specifies the alignment of the rib:

Bottom

The rib is attached to the bottom of the slab. The eccentricity is calculated automatically as the sum of the half of slab thickness and the distance from the bottom slab face to the centroid of the cross-section.

Top

The rib is attached to the top of the slab. The eccentricity is calculated automatically as the sum of the half of slab thickness and the distance from the top slab face to the centroid of the cross-section.

Centre

Middle axis of the rib and the slab are coincident. The final eccentricity is equal to zero. The calculation model shows a partial doubling of stiffness of the (i) slab and (ii) the rib.

Shape of rib

There are several possible shapes of the rib

  • T symmetric: the effective width is defined as a single value, placed symmetrically on both sides of the beam
  • slab right: the effective width is taken in account only on the right-hand side of the rib in the view against the positive x axis of the rib (the right side of the profile)
  • slab left: the effective width is taken in account only on the left-hand side of the rib in the view against the positive x axis of the rib (the left side of the profile)
  • slab non-sym: the effective width is defined separately on the left- and right-hand side of the beam and can therefore be assymetrical
  • automatic: the effective width is calculated by the program (see details in "Automatic calculation of the effective width of plate ribs")

Effective width

Specifies how the effective width is defined:

Default

The effective width is determined as a multiple of rib width. The multiple can be defined in Calculation, Mesh > Solver setup > Number of thicknesses of rib plate.

Width

The effective width is explicitly specified. The value can be input below.

Number of thicknesses

The effective width is determined as a multiple of the thickness. The multiple can be input below this parameter.

for internal forces

Two types of effective width can be input. Both the value are used for the modelling of composite cross-section. Value "for internal forces" is used to recalculate internal of the created composite cross-section section. Value "for check" (see below) is used to define the cross-section for the needs of design and check of reinforced cross-section.

Usually, a rectangular section is attached to the slab creating the final T or L section. However, also other library cross-sections can be used to form various composite sections (e.g. steel I section + concrete reinforced plate).

for check

See above.

FEM type

Defines the type of finite element:

Standard

The standard 1D finite element is used. The element can transfer both moments, axial and shear forces.

Axial force only

Truss finite element is applied. This element is capable of transferring the axial force only.

Buckling and relative lengths

Can be used to specify buckling lengths.

Layer

Specifies the layer of the rib.

2D member

Informs about the "associated" slab.

Geometry parameters

These parameters are shown in the property window of an already defined rib. They are not displayed when a new rib is being defined.

Length

Tells the length of the rib.

Shape

Informs about the shape of the entity.

Beg. node

Specifies the starting node of the rib. This parameter can be edited, which would affect the location and length of the rib. Before editing, you must find the name of node you want to use as the beginning node.

End node

Similar to above. Defines the end-node of the rib.

Structural model

This set of parameters can be used to specify the structural model of the rib. The structural model is important especially if drawings and/or impressive pictures of the structure are to be made.

See chapter Geometry > Structural model > Parameters of structural model for more details.