Case 2

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Good Practices

Design

Tall slender concrete structures should be designed with due consideration of the effects of lateral deflection and be within acceptable vibration limits in accordance with BS EN 1992-1-1, SS EN 1992-
1-2, CP 65-1 or equivalent. Any deflection/deformation of the concrete structure due to vertical loading
should be compatible with the degree of movement acceptable by other elements (i.e., the finishes,
services, partition, glazing and cladding) in accordance with BS EN 1992-1-1 or equivalent. Limit State Method should be considered for design and verification of structure for durability of façade structures. Refer to modelling of deterioration process in accordance with ISO 13823 or equivalent.

The causes, effects and methods of prevention and repair for cracks (e.g., longitudinal cracks, transverse
cracks, cracks above prestressing strands, web crack at or near the prestressing strands, corner crack, and miscellaneous cracks) in precast concrete wall panels should be considered and applied in accordance with BS EN 13369, SS 677 or equivalent. Limit the design crack width with reference to CP 65-2 or equivalent. Laboratory mechanical tests should be carried out to measure deformations on horizontal joints between load-bearing walls and concrete floors in accordance with ISO 7845

Construction

Use two-stage joints for precast façade construction to ensure higher watertightness performance, since doing so will avoid seepage through hairline cracks, as is the case with one-stage joints in accordance with SS EN 1992-1-2 or equivalent. Seal off horizontal joints for load bearing walls with non-shrink grout.
Minimise cracks in rendered brick walls by using appropriate mix ratio, thickness and number of coats.
Provide bonding bars at interfaces between different materials in order to minimise cracks (e.g., where a brick wall abuts concrete). Alternatively, the bonding bars can be cast together with the concrete member.

At the completion of the construction stage, minor repair work or fixing adjustments may be acceptable. Enhance the durability of vulnerable parts of construction; ensure that surfaces exposed to water are freely drained; provide adequate cover to steel; use protective coatings for either steel or the concrete, or
both in accordance with BS EN 1992-1-1, SS EN 1992-1-1, SS EN 1992-1-2, CP 65-1 or equivalent. Make accessible components of which predicted service life is less than the design life of the structure for inspection, and replace them in accordance with ISO 13823 or equivalent.

Concrete

Design

An understanding of the environment /atmospheric conditions should be taken into consideration during the design stage.

EnvironmentExposure conditions
MildConcrete surfaces protected against weather or aggressive conditions
ModerateExposed concrete surfaces but sheltered from severe rain or severe traffic
Concrete surfaces continuously under non-aggressive water
Concrete in contact with non-aggressive soil
Concrete subject to condensation
SevereConcrete surfaces exposed to severe rain, alternate wetting and drying or occasional freezing or severe condensation
Concrete surfaces occasionally exposed to light traffic
Very severeConcrete surfaces occasionally exposed to seawater spray (directly or indirectly)
Concrete surfaces exposed to corrosive fumes and heavy traffic
Most severeConcrete surfaces frequently exposed to seawater spray (directly or indirectly) and heavy traffic
AbrasiveConcrete surfaces exposed to abrasive action

Table 1: Classification of exposure conditions [6]

Material

Cement should comply with SS EN 197 series while coarse and fine aggregates used should comply with SS EN 12620. All aggregates shall be stored in clean places [7]. Table 2 shows the various concrete grade to be achieved.

Concrete Grade3035404550
Minimum cement content (kg per m3)275300325350400
Maximum cement content (kg per m3)550550550550550
Maximum % of Fine Aggregate to Total Aggregate5050505050
Maximum water to cement ratio0.550.500.450.400.40

Table 2: Designed mix of concrete [7]

Construction

Ready mix concrete is preferred over site mixed concrete to achieve consistency.

Check for quality of concrete before placing [8]. e.g. water cement ratio, slump test, etc.

Place the concrete carefully. If concrete is placed directly from a truck or concrete pump, place concrete vertically into position. Do not allow the concrete to fall more than 1 to 1.5 metres.

Ensure thorough compaction of the concrete during placement.

Quality control

Avoid following during concreting to minimize cracks:

  • Avoid excessive manipulation of the surface, which can depress the coarse aggregate, increase the cement paste at the surface, or increase the water-cement ratio at the surface.
  • DO NOT finish the concrete before it has completed bleeding.
  • Do not dust any cement onto the surface to absorb bleed water.
  • Do not sprinkle water on the surface while finishing.

Reinforcement

Design

Sufficient concrete cover should be provided to prevent corrosion of reinforcement.

Condition of exposureNominal cover    
Mild2520202020
Moderate35302520
Severe403025
Very severe504030
Most severe50
Abrasivesee note 3see note 3
Maximum free water/cement ratio0.650.600.550.50.45
Minimum cement content (kg/m3)275300325350400
Lowest grade of concreteC30C35C40C45C50
1) This table relates to normal-weight aggregate of 20mm nominal size. Adjustments to minimum cement contents for aggregates other than 20 mm nominal maximum size are detailed in BS EN 206+A2.

Table 3: Limiting values of the nominal cover of normal weight aggregate concrete [6]

Material

All high yield reinforcement bars should comply with SS 2 and welded steel fabric should comply with SS 32 [7]

Reinforcement can be protected further by using following methods:

  • removal of rust and mill scale before embedment
  • use of non-metallic coatings such as epoxy resins and solvent containing acrylic resins [9]
  • use of metallic coatings such as zinc and nickel
  • Cathodic protection
  • use of corrosion inhibitors
  • use of corrosion resistance reinforcement (eg. stainless steel)
  • use of low permeability concrete, with improved resistance to chloride ion ingress