Driven pile foundations are widely used in construction to support structures by driving piles into the ground. Driven piles can be made of materials like steel, concrete, or timber. Heavy equipment, such as pile drivers, is used for their installation. This article will explore the benefits of driven pile foundations. It will cover their speed and efficiency. Additionally, we will discuss the differences between driven pile vs bored pile systems. We will also cover topics like precast driven piles and the various techniques used during driven pile installation. Understanding these details will help in selecting the right foundation type for different projects, ensuring stability and cost-effectiveness. Stay tuned for insights on why driven piles are preferred in many scenarios.
Driven piles are a type of deep foundation used to support structures. They transfer loads to the underlying soil or rock. Also known as displacement piles, driven piles can be made from steel, concrete, or wood. The installation process involves driving these piles into the ground using impact hammers or vibratory drives. They continue until the piles reach a stable layer of rock or soil. This layer must be capable of bearing the required loads.
In cases where the soil is exceptionally dense, pre-drilling may be necessary. This ensures the driven pile reaches the designated depth. Driven pile foundations provide a cost-effective approach. They enhance the stability and strength of various structures. These include buildings, tanks, towers, walls, and bridges. Recognizing whether to use driven piles or bored piles is essential. It helps in selecting the right foundation type for specific construction projects.
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Why driven piles?
Contractors often use driven piles for cost-effective deep foundation solution. They support buildings, tanks, towers, walls, and bridges. They are also suitable for embankments, retaining walls, bulkheads, anchorage structures, and cofferdams. Driven piles possess a high load-bearing capacity, durable, and contractors can install them quickly and effectively in various soil conditions. Engineers frequently use them in places with inadequate soil. Conventional shallow foundations are not strong enough to sustain buildings in those areas.
In addition, contractors can install driven piles to support compression, tension, or lateral loads. Specifications are determined by the structure’s needs, budget, and soil conditions. This makes them very versatile.
Types of driven piles
Driven piles are broadly classified as follows
- Steel Driven pile
- Precast Concrete Driven pile
- Timber pile
- Composite driven pile
Steel Driven pile
Steel-driven piles support major structures such as buildings, bridges, roads, and industrial facilities in construction. Construction workers push them into the earth using specialized tools like hydraulic hammers or pile drivers until they reach a predetermined depth or a firm layer of rock or soil. Steel-driven piles are steel beams with broad flanges on both ends.
Steel-driven piles typically consist of high-strength steel with a round or square cross-section. Contractors can obtain them in various lengths and widths, allowing for vertical or angled installation to meet foundation design requirements. Workers use an impact hammer to drive the pile into the soil by delivering a forceful blow. For shorter depths, they support steel screw piles with a cast iron helix and power them using rotary motors.
The steel-driven pile is a common choice for deep foundations because of its durability and strength. It can support enormous loads. Steel-driven piles are a cost-effective and quick solution for many construction projects. However, their applicability will depend on factors such as soil characteristics, anticipated loads, and local construction building codes and regulations.
Pre-cast concrete Driven Piles
Precast concrete pile manufacturers deploy these piles in construction to support structures built on weak or compressible soils. They prefabricate these piles in a factory or casting yard before transporting them to the construction site. They can construct precast concrete piles in various dimensions. The forms and configurations depend on the project’s unique needs. High-strength concrete, reinforced with steel rebar, is used to make these piles. They often use a vibratory hammer or hydraulic hammer to drive the piles into the earth until they reach the required depth or a solid layer of soil or rock.
Piles come in a variety of shapes, such as square, octagonal, cylindrical, or sheet. Percussion-driven piles are used in situations where bored piles would be ineffective due to running water or excessively loose soils. They have a load range of 300-1,200 kN and a maximum reach of 30 m. Precast concrete piles are constructed with great accuracy and quality control in a controlled environment, resulting in a consistent and uniform product that satisfies design requirements. They are durable and can withstand adverse weather conditions such as seawater or chemical exposure. Precast concrete piles can also be installed quickly and effectively, saving time.
- Precast concrete piles are quick to install.
- They can be used in various soil conditions.
- Using precast concrete piles saves time and money in construction.
- Precast concrete piles are durable and reliable.
- They have high-quality control standards.
- Precast concrete piles are a popular choice for deep foundation construction.
Timber pile
Timber-driven piles are used in construction to create a stable foundation for structures in weak or compressible soils. Contractors use hammers or pile drivers to create cylindrical or square wood piles from premium softwood species. This type of pile is particularly effective in areas with high water tables where other types of piles may not work as well. Timber-driven piles provide a stable foundation for structures in weak or compressible soils. This is achieved by hammering wooden piles into the ground, which compresses the wood and displaces the surrounding soil. The resulting tight fit helps to support the weight of the structure. Timber-driven piles have the advantages of being inexpensive and simple to install. Nonetheless, they may be susceptible to rot and pest infestation.
Composite driven pile
Engineers commonly use composite piles made of a combination of two or more materials, such as concrete, steel, or timber, when soil conditions require a combination of strength and flexibility. An example of a composite pile is a concrete pile with a steel section, as shown in the figure.
Contractors use composite-driven piles consisting of a steel tube filled with concrete and reinforced with steel rebar because they can withstand heavy loads. They use in various construction projects, such as bridges, high-rise buildings, and marine structures. The steel tube provides structural support and protects the concrete from damage during installation, while the concrete and rebar provide additional strength and stability. Contractors can install composite piles using hydraulic hammers or vibratory drivers to reach depths of up to 60 meters. Due to their durability and corrosion resistance, composite piles are ideal for use in harsh environments.
Quality Control for Driven Piles
The construction of driven piles requires high-quality materials and adherence to standards such as BS 8004:2015 and EC standards. It’s crucial to maintain the pile’s shape and avoid damage during installation and inspect them beforehand for quality assurance. The maximum load a pile can carry depends on soil or rock strata properties, pile dimensions and material, and installation method. Engineers perform load testing on representative samples to determine capacity and use monitoring instruments like inclinometers and settlement gauges to ensure the pile’s sufficient support. Effective quality control and testing are crucial for the safe and reliable performance of driven piles in construction projects.
During installation, it is crucial to maintain the shape of driven piles and ensure they are not damaged by the installation of subsequent piles.
Quality control of driven piles is an important aspect of ensuring the stability, safety, and longevity of structures that rely on them for support. Here are some of the common quality control measures used for the driven piles.
Pile driving equipment for driven piles
Trained personnel are essential for correct pile installation. They must maintain, calibrate, and operate pile driving equipment properly. Regular inspections are necessary to detect any damage or wear in the equipment, and repairs or replacements must be made promptly.
Pile inspection and testing
Inspect the piles for defects or damage before driving them into the ground. To ensure that the piles have been installed correctly and meet the specified requirements, non-destructive testing methods such as sonic testing or integrity testing should be used to test the piles after installation.
Pile load testing for driven pile
One can conduct load testing of a sample of piles to ensure that they can support the required loads. This involves applying a controlled load to the pile and measuring the resulting deformation, which one can compare to the design specifications to ensure that the piles are safe and reliable.
Pile driving records
One should keep detailed records of the pile driving process, including the number of blows or vibrations required to drive the pile to the required depth, the penetration rate, and any other relevant information. These records are essential to monitor the quality of the installation and identify any issues that may arise during the construction process.
Regular inspections and testing are essential to identifying any issues early in the construction process and enabling prompt corrective action.
Advantages of driven piles
The main advantages are
- Piles can be pre-fabricated off-site which allows for efficient installation once on-site.
High Capacity
Piles are driven deep into soil or rock, which provides a high load-bearing capacity. Consequently, this method is suitable for supporting heavy structures like buildings, bridges, and marine structures. Moreover, the process increases the effective length of the pile, resulting in enhanced capacity. Thus, driven piles offer an efficient solution for ensuring stability and strength in various construction projects.
Ease of Installation of driven piles
Compared to other pile types like drilled shafts, the installation of a driven pile is quick and efficient. The installation process involves driving the piles into the ground using an impact hammer or a vibratory driver. This requires minimal excavation and soil removal.
Cost-effective
Other types of foundation systems can often be more expensive than driven piles, particularly when the soil conditions are favourable. The cost-effectiveness of driven piles is due to their relatively simple installation process and the availability of pre-manufactured piles, which can reduce the time and cost required for pile installation.
Minimal disturbance
The installation process of driven piles minimizes the disturbance to the surrounding area, making them suitable for use in urban or environmentally sensitive areas. The piles are driven into the ground, which reduces the amount of soil disturbance and the need for excavation.
Versatility
Driven piles are suitable for a variety of soil conditions, including soft soils, hard soils, and rock layers. They can also be made of different materials such as steel, concrete, and timber, providing a wide range of design options.
- When driven into the ground, piles displace and compact the soil, resulting in increased bearing capacity. In contrast, other types of deep foundations may require soil removal, which can cause subsidence and structural problems.
- Installation usually produces little spoil for removal and disposal.
Overall, driven piles offer several advantages in terms of high capacity, speed of installation, cost-effectiveness, minimal disturbance, and versatility, making them a popular choice for foundation systems in many construction projects.
However, the use of driven piles also has some disadvantages, including their relatively high cost compared to shallow foundations, the noise and vibration associated with their installation, and the potential for damage to nearby structures or utilities. Therefore, the selection of driven piles as a foundation type depends on a variety of factors, including soil conditions, load requirements, and site-specific constraints.
Disadvantages of driven piles
In the design and construction process, it is important to consider the disadvantages of driven piles, despite their many advantages. Some of the main disadvantages of driven piles are:
Noise and vibration
The installation of driven piles can generate high levels of noise and vibration. This can be a concern for nearby residents and sensitive structures. Pile driving can cause damage to nearby structures, particularly those with shallow foundations.
Limited depth
Other foundation types may be necessary if the capacity or depth required cannot be achieved with driven piles. This is because of the limitations imposed by soil or rock conditions and the driving equipment’s capacity.
Difficulty in driving through hard soil or rock
Driving piles in hard soil or rock layers can be difficult and time-consuming, which can lead to higher installation costs. Overcoming the hardness of the soil or rock may also require the use of specialized driving equipment or techniques.
Quality Control
The installation of a driven pile requires critical quality control. Poor installation can cause issues such as pile damage, pile movement, or insufficient load capacity. To ensure that the piles are installed correctly and meet the required standards, regular inspection, and testing are required. Moreover, monitoring is necessary during pile installation.
Limited environment suitability
Driven piles may have limited suitability in environmentally sensitive areas. This includes wetlands or areas with a high water table. This is due to the potential soil disturbance caused by the driving process. Moreover, the use of chemicals for the preservation or treatment of piles can have negative impacts on the environment. It is important to consider these factors and explore alternative foundation options in such areas.
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