As urban construction advances, geotechnical engineering finds increasing applications in various sectors such as construction, transportation, and water conservancy. In geotechnical engineering, slope stability is a critical issue. Slope instability can result in disasters like landslides and collapses, posing a significant threat to both lives and property. Ensuring slope stability often involves the application of rock bolt technology by engineers and technicians to reinforce the structure. So, how do rock bolts stabilize slopes?
Rock bolts are a fundamental part of tunnel support in contemporary coal mines. They reinforce the surrounding rocks of the tunnel and play a supporting role. It is attached to the engineering structure at one end, and the other end is deep in the stratum, which is a tensile member. The whole anchor contains an anchoring section and a free section, which consists of a pallet, anchor, nut, and washer.
Rock bolt support involves strategically placing a specified number and type of rock bolts in rock or soil slopes. These rock bolts are deeply embedded within the slope, utilizing preset tension to withstand both groundwater pressure and the weight of the slope. Under constant pressure, the displacement of the formation is controlled through bending strength and friction to achieve stability. Rock bolt support can effectively utilize the strength of the rock and soil mass to reduce the deformation and internal force of the supporting structure and improve the safety of the project. With increasing soil depth, the benefits of rock bolt support become more apparent. Compared to traditional support methods, rock bolt support proves to be a more economical and efficient alternative.
Rock bolt support serves to fortify slopes, playing a significant role in ensuring the long-term stability of rock formations. In practical applications, rock bolt support is extensively employed in projects such as highways and high-speed rail tunnels, demonstrating commendable reinforcement effects.
Earthquake and freeze-thaw are two important influencing factors of slope stability. And in the case of these natural disasters, rock bolt support can play a certain role in resistance. The design of an anchor network can slow down the influence of earthquakes and freeze-thaw on the surrounding rock to a certain extent to reduce the risk of earthquake disasters and slope landslides.
The advantage of rock bolt support is that it can improve the construction efficiency of the project. Rock bolt support can provide a faster reinforcement solution than traditional support methods, thus reducing construction time and costs.
Urbanization has led to the gradual filling or alteration of numerous slopes characterized by weak geological conditions and steep terrain. Consequently, a plethora of slope engineering projects has emerged. Addressing these projects requires a comprehensive approach, encompassing considerations and solutions for slope stability in design, construction, monitoring, and maintenance. The introduction of the rock bolt support method not only addresses the challenge of load resistance for numerous buildings in rugged terrains but also offers a simple, rapid, and efficient means to control slope movement and deformation. This approach effectively minimizes slope displacement during movement, making slope engineering more viable by managing internal pressure.
In real-world engineering applications, ensuring the stability and effectiveness of rock bolts requires careful consideration of the following factors:
Qualitative analysis and assessment of slope stability are conducted based on the engineering geological conditions of the slope. However, its limitation lies in the inability to perform quantitative evaluation.
It is a qualitative evaluation method by comparing two or more slopes that are generally similar and inferring the similarity of other attributes based on their attributes.
Through the statistics of a large number of structural planes, the application of red flat projection, solid proportion projection, and friction circle method to judge the stability of the slope is also a qualitative evaluation method, which is difficult to quantify.
This method takes the sliding body as a rigid body and analyzes its equilibrium state along the sliding surface. Commonly used methods include the Fellenius method, the Bishop method, and the Sarma method. The main advantage is simplicity. The disadvantage is that the rock mass is treated as a rigid body and cannot reflect the real stress-strain relationship inside the rock mass; the stability coefficient is the average value on the sliding surface, with a certain degree of assumptions, but also can not consider the effect of progressive damage on the stability of the various calculation methods themselves have different assumptions, all have a definite scope of application and limitations, are the super-static problem into a static problem to deal with.
Numerical analysis methods commonly used in slope stability evaluation include the finite element method, boundary element method, discrete element method, etc. These numerical analysis methods offer high accuracy, but they are susceptible to the influence of geological models, simplified mechanical models, and mechanical parameters. As a result, achieving “highly accurate” evaluations of “high-precision” calculation results can be challenging.
This method is based on the principle of limit equilibrium to establish the equation of state and based on the method of fixed stability coefficient, the method of calculating the probability of slope instability. The advantage of this method is to solve the problem of uncertainty in slope stability, but its disadvantage is that it needs a large number of statistical samples; secondly, it is established based on the limit equilibrium method, so it contains the defects and limitations of limit equilibrium method.
In conclusion, the rock bolt support method stands out as a crucial element in slope engineering design and stability solutions. Its significance lies in enhancing the tensile capacity of slopes, improving overall slope stability, and facilitating increased groundwater penetration. This method finds widespread application in practical projects due to its proven effectiveness in addressing these critical aspects of slope management. In specific engineering practice, we should fully consider geological conditions, slope types, and other factors, and rationally select and apply rock bolt technology to achieve long-term stability of the slope and ensure project safety.