Foundations are critical structural components that transfer loads from a building’s superstructure to the underlying soil or rock. They must be strong, stable, and reliable to ensure the safety and longevity of structures such as buildings, bridges, docks, and other infrastructure. Foundations are classified into several types based on their design, material, and application.
Each column has its footing, which can be either rigid (without reinforcement) or flexible (with reinforcement). Flexible footings use steel reinforcement to reduce foundation depth and base area, making them more cost-effective when excavation depth or foundation size is restricted.
Rigid Footings: No reinforcement; relies on concrete strength.
Flexible Footings: Reinforced with steel, allowing for shallower depths.
Cross-Shaped Footings: Used in special cases (e.g., seismic zones or poor soil conditions).
Strip footings are long and narrow, with a length 10 times greater than their width. They are categorized into:
Wall Footings: Support load-bearing walls.
Column Footings: Aligned along axes, sometimes connected to isolated footings.
Key Features:
Primary reinforcement runs transversely (main load-bearing direction).
Secondary reinforcement runs longitudinally (distribution reinforcement).
When soil bearing capacity is low and building loads are high, a raft foundation distributes the load across a large area. This monolithic slab supports the entire structure, reducing soil pressure and minimizing differential settlement.
Advantages:
Enhances structural integrity.
Effective for weak or compressible soils.
A reinforced concrete structure consisting of a base slab, top slab, and intersecting walls, forming a hollow box. It provides high rigidity, making it ideal for:
High-rise buildings.
Structures on soft soil with heavy loads.
Underground spaces (e.g., basements).
Used when shallow soil layers cannot support structural loads, pile foundations transfer weight to deeper, more stable strata.
High-rise buildings require minimal settlement.
Seismic-resistant structures.
Offshore and marine constructions.
End-Bearing Piles: Rest on solid bedrock or dense soil.
Friction Piles: Rely on soil adhesion along the pile shaft.
Precast Piles: Driven into the ground (high strength but costly).
Cast-in-Situ Piles: Concrete poured into drilled holes (economical but weaker).
Materials Used:
Concrete Piles: Most common, prefabricated or cast in place.
Steel Piles: High load capacity but expensive (e.g., H-beams,钢管桩).
Timber Piles: Rarely used today due to durability issues.
High Pile Caps: Above ground level (used in bridges, ports).
Low Pile Caps: Below ground level (common in buildings).
Constructed using the slurry trench method, these reinforced concrete walls serve as deep supports for bridges and heavy structures.
Two Main Types:
Separate Walls: Arranged according to load distribution.
Enclosed Walls: Forming a polygonal or rectangular cell topped with a cap.
Choosing the right foundation depends on soil conditions, structural loads, and environmental factors. From shallow footings to deep pile systems, each type offers unique advantages for ensuring stability and durability in construction projects.
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