Example 3|www.BuildingHow.com

VOLUME A
The art of construction and detailing
Introduction
The structural frame
- Introduction
- Structural frame elements
  - Columns
  - Beams
  - Slabs
  - Staircases
  - Foundation
- STRUCTURAL FRAME LOADING
- BEHAVIOR OF THE STRUCTURAL FRAME
  - The behavior and reinforcement of a slab
  - Behavior and reinforcement of beams and columns
Construction methods
- The materials
- The moulds
- Thermal insulation of structural elements
- Concrete
- The steel
- Reinforcement specifications of antiseismic design
- Industrial stirrups - stirrup cages
- Standardized cross-sections of reinforced concrete elements
Reinforcement
- Columns
- Shear walls
- Composite elements
- Beams
- Slabs
- Staircases
- Foundation
Quantity surveying
- Estimation of the concrete’s quantity
- Estimation of the formworks’ quantity
- Estimation of the spacers’ quantity
- Estimation of the reinforcements' quantity
- Total estimation of the materials’ quantities
- Optimization of the reinforcement schedule
- Estimation of the structural frame’s cost
- Electronic exchange of designs - bids - orders
Detailing drawings
- General
- The drawings’ title block
- Carpenter’s drawings
- Steel fixer’s drawings
Tables
- Table 1
- Table 2
- Table 3
Drawings
- Carpenter’s drawings
- Steel fixer’s drawings
Model (exemplary) construction

« Example 2 Clarifications »

Example 3

(project <Β_422-3>)

Region of three-edge- supported slabs

Figure 4.2.3-21: Shear force envelopes

The most unfavourable shear forces are equal to:

Middle cross-section in x: V_xr=23.1 (21.1) [*]NoteThe respective results corresponding to global loading are shown in brackets. , V_x,erm=-37.0 (-36.4) [kN]
End cross-section in x: V_xr=25.8 (23.1), V_x,erm=-38.8 (-38.3) [kN]
y direction: V_y,erm=-34.6 (-31.3) [kN]

Figure 4.2.3-22: Front view of the 3D shear force diagrams, corresponding to the envelope of [V_x]

Figure 4.2.3-23: Side view of the 3D shear force diagrams, corresponding to the envelope of [V_y]

Note that although the live load has a relatively high value, the differences between the shear forces do not exceed 9%.

Figure 4.2.3-24: Bending moment envelopes

The most unfavourable bending moments are equal to:

Middle cross-section in x: Μ_x=16.5 (13.8) [*]NoteThe respective results corresponding to global loading are shown in brackets. , M_x,erm=-26.7 (-26.6) [kNm]
End cross-section in x: M_x=20.3 (16.9), M_x,erm=-29.9 (-29.9) [kNm]
y direction: M_y=3.5 (2.8), M_y,erm=-20.5 (-17.4) [kNm]

Figure 4.2.3-25: Front view of the 3D bending moment diagrams, corresponding to the envelope of [M_x]

(Fig. 4.2.3_26) Side view of the 3D bending moment diagrams, corresponding to the envelope of [M_y]

Notice that although the live load has a relatively high value, the differences between the bending moments are small.

Figure 4.2.3-27: Deflection envelopes

Maximum deflections of y=-1.58 (-1.14 ) [*] Note NoteThe respective results corresponding to global loading are shown in brackets. mm occur at the free edges of the three-edge-supported slabs. At the same edges opposite sign deformation of y=0.23 mm is also developed.

In the middle cross-section of the slabs the extreme deflections are y=-1.30(- 0.94) mm and y=0.18 mm respectively.

Figure 4.2.3-28: Front view of the 3D deflection diagrams

Figure 4.2.3-29: Side view of the 3D deflection diagrams

Note that the deflections are quite higher reaching up to 40% and, at the same time, opposite sign deformations also arise (blue lines).

Cantilever region

Figure 4.2.3-30: Shear force envelopes

The most unfavourable shear forces are equal to:

Two-way in x: V_xr=20.0 (18.6) [*]NoteThe respective results corresponding to global loading are shown in brackets. , V_x,erm=-35.7 (-33.6) [kN]
Cantilever in x: small shear forces
Two-way in y: V_yr=34.6 (31.4), V_y,erm=-38.0 (-35.9) [kN]
Cantilever in y: V_y,erm=54.3 (46.9) [kN]

Figure 4.2.3-31: Front view of the 3D shear force diagrams, corresponding to the envelope of [V_x]

Figure 4.2.3-32: Side view of the 3D shear force diagrams, corresponding to the envelope of [V_y]

Notice that although the live load has a relatively high value, the differences between the shear forces do not exceed 6% except for the peak of the cantilever middle support reaching 15%.

Figure 4.2.3-33: Bending moment envelopes

The most unfavourable bending moments are equal to:

Two-way in x: Μ_x=11.9 (8.0) [*]NoteThe respective results corresponding to global loading are shown in brackets. , M_x,erm=-22.8 (-19.9) [kNm]
Cantilever in x: small moments
Two-way in y: Μ_y=6.0 (4.9), M_y,erm,1=-20.5 (-17.4) and M_y,erm,2=-31.6 (-30.6) [kNm]
Cantilever in y: extended M_y,erm=-31.6 (-30.6), peak -45.8 (-41.3) [kNm]

Figure 4.2.3-34: Front view of the 3D bending moment diagrams, corresponding to the envelope of [M_x]

Figure 4.2.3-35: Side view of the 3D bending moment diagrams, corresponding to the envelope of [M_y]

The differences between the unfavourable bending moments and the bending moments due to global loading, range from 15 to 50%.

Figure 4.2.3-36: Deflection envelopes

Maximum deflection of y=-0.96 (-0.64) [*] Note NoteThe respective results corresponding to global loading are shown in brackets. mm and opposite sign deflection of y=0.31 (0.09) mm occur in two-way slabs.

In cantilever slab the maximum deflection is y=-3.11 (-2.81) mm.

Figure 4.2.3-37: Front view of the 3D deflection diagrams

Figure 4.2.3-38: Side view of the 3D deflection diagrams

The slightly fluctuating deformations of the cantilever longitudinal free edge, are due to the fluctuations of the two-way slabs deformations behind the cantilever.

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