Abstract
Rock sheds have been widely used to protect against rockfall. Traditionally, a cushion layer is placed on the top of a rock shed to reduce the impact force and dissipate energy. However, heavy cushion layers lead to high dead loads and increased construction costs. This paper discusses the concept of an impact‐resilient flexible buffer structure. On the basis of that concept, it also proposes a buffer structure mainly composed of springs, ring nets, spring rods, and support ropes, which can be used to replace the traditional cushion layer on a shed for rockfall protection. Full‐scale impact tests were conducted to study the impact‐resilient characteristic of the structure combined with numerical simulation. The dynamic responses of the buffer structure, including force, deformation, and energy dissipation, were analysed in depth. Finally, parametric numerical simulations of 33 models were conducted; the spring stiffness of these models ranged from 300 kN/m to 1500 kN/m; the impact energy ranged from 100 kJ to 2000 kJ. Moreover, simple approaches for estimating the impact force and braking distance of the buffer structure were proposed and verified using measured data obtained from the impact test.
Highlights
Rockfall is one of the most common natural hazards in mountainous regions with the characteristics of high frequency and unpredictability
Kawahara and Muro [4] found that an increase in the thickness of sand cushion can effectively reduce the impact force, and this effect increases as the dry density of the cushion material decreases
Sun et al [14] studied the buffering performance of a rubber tire cushion using 12 impact tests; they reported that rubber tires can significantly reduce the impact force, and the buffering performance will be further enhanced when the tire is filled with sand or gravel
Summary
Rockfall is one of the most common natural hazards in mountainous regions with the characteristics of high frequency and unpredictability. Cushion layers (Figure 1(a)), usually composed of sand or soil, are commonly placed on the top of a rock shed to reduce the impact force and dissipate energy [1,2,3,4,5,6,7,8,9]. On the basis of that concept, it proposes an impact-resilient flexible buffer structure mainly composed of ring nets, supporting ropes, spring rods, and spring coils. A fullscale buffer unit was designed, and two impact tests, with an impact energy of 25 kJ and 50 kJ, respectively, were conducted in succession to study the impact-resilient characteristic of the structure combined with numerical simulation. Simple approaches for estimating the impact force and braking distance of the buffer structure were proposed using 33 parametric numerical simulations and verified using measured data obtained from the impact test
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