Working Principle of Self-Drilling Rock Bolts in Geotechnical Engineering

Introduction

Self-drilling rock bolts (SDA bolt), also known as hollow anchor bars, have revolutionized modern geotechnical engineering by combining drilling, grouting, and anchoring into a single streamlined process. Their ability to adapt to complex geological conditions—such as loose soils, fractured rock, or water-saturated strata—makes them indispensable in projects like slope stabilization, tunnel reinforcement, and deep foundation support. This article delves into their design, working principles, and real-world applications, backed by technical insights from industry practices.

Components of Self-Drilling Rock Bolts

A self-drilling rock bolt system comprises six critical parts:

1. Drill Bit: Attached to the bolt’s tip, it penetrates rock or soil.
2. Hollow Anchor Bar: A threaded, perforated steel tube that acts as a drill rod, grout channel, and reinforcement.
3. Couplers: Enable bolt extension by connecting multiple hollow bars.
4. Plate: Distributes load across the surface.
5. Nut: Applies tension to the bolt after installation.
6. Centralizers: Ensure even grout distribution around the bolt.

Working Principle of Self-Drilling Rock Bolts

1. Drilling Mechanism

The hollow anchor bar serves dual roles: a drill rod and a conduit for grout. Powered by a rotary drill rig, the bolt is driven into the ground while simultaneously clearing debris via compressed air or water injected through its hollow core. This “drill-in-place” method eliminates the need for temporary casing, even in unstable strata prone to collapse.

Key Features:

• Continuous Threads: Allow seamless coupling for extended drilling depths.
• Debris Removal: Air/water flushes cuttings, maintaining borehole integrity.
• Adaptability: Compatible with diverse drill bits (e.g., cross carbide, button bits) for varying rock hardness.

2. Grouting Process

Post-drilling, cement grout is pumped through the hollow bar, exiting via ports in the drill bit. The pressurized grout fills fractures, voids, and the annular space around the bolt, creating a reinforced composite structure. Notably, the grout’s radial expansion generates an “over-drilled” effect, enlarging the anchor diameter by 20–70 mm beyond the drill bit size, significantly enhancing pull-out resistance.

Grouting Advantages:

• Borehole Stabilization: Prevents collapse in loose soils.
• Improved Bonding: Irregular grout-soil interfaces increase frictional resistance.
• Corrosion Protection: Grout shields the steel from environmental degradation.

3. Anchoring Mechanism

Once grout cures, the bearing plate and nut are installed to apply pre-tension (if required). The bolt interacts with the surrounding mass through:

• Frictional Resistance: Load transfer via shear stress between the grout and soil/rock.
• Mechanical Interlock: Threaded bars bond with grout, resisting axial and lateral forces.
• Structural Integration: Anchors form a compressive zone, redistributing stresses to stabilize weak zones.

Functional Roles in Anchoring:

• Wedge Effect: Bolts traverse discontinuities, preventing block movement.
• Suspension: Stabilizes surface layers by anchoring them to deeper, stable strata.
• Composite Beam: Multiple bolts create a reinforced “beam” to resist bending.
• Pre-Stressing: Active load application counters deformation in slopes or excavations.

Applications in Geotechnical Engineering

1. Slope Stabilization

In landslides or steep slopes, self-drilling bolts are installed at calculated angles to form a tension-resistant network. Grout consolidates fissured rock, while the bolts’ tensile capacity counters shear failure. Example: A Huangshan excavation used R38 bolts to secure a mixed strata slope, avoiding costly casing methods.

2. Tunnel and Underground Support

As tunnel boring progresses, bolts act as forepoling pipes in weak rock (e.g., Class IV/V). They create a load-bearing arch, reducing radial deformation and preventing collapses. Compared to conventional methods, SDA systems merge drilling and grouting, halving construction time.

3. Deep Foundation and Micro-Piling

For high-rise foundations or retrofitting, bolts function as micro-piles. Grouted bars transfer structural loads to competent layers, mitigating differential settlement. They are ideal for confined spaces due to modular assembly.

4. Earthquake and Disaster Mitigation

Post-disaster, bolts reinforce destabilized structures by grouting fractured zones. For instance, they were used in Guizhou to stabilize a collapsed hydropower tunnel filled with debris.

Advantages Over Conventional Anchors

1. Efficiency: Combines drilling, grouting, and anchoring into one step, reducing labor and time by 50%.
2. Versatility: Suitable for gravel, sand, weathered rock, and urban sites with vibration/noise constraints.
3. Cost-Effectiveness: Eliminates casing and secondary grouting, lowering material costs.
4. Enhanced Performance: Over-drilled grout bodies offer superior load capacity compared to traditional anchors.

Conclusion

Self-drilling rock bolts exemplify innovation in geotechnical engineering, offering a robust solution for modern infrastructure challenges. By integrating drilling and grouting, they ensure rapid, reliable stabilization across diverse terrains—from landslide-prone slopes to urban tunnels. As technologies advance, expect further refinements in corrosion resistance, automated installation, and smart monitoring systems, solidifying their role in sustainable construction.