The present invention provides an explosive method that improves on methods currently employed. The present invention provides for a safer, less expensive, and more portable explosive device. The elements of the present invention replace dynamite or similar explosives currently used in avalanche control and bore hole blasting of rock or other solids. The present invention comprises an apparatus and a method providing a much safer alternative employing a highly confined combustion reaction of a flammable vapor, whereas dynamite is a category 1.1 high explosive imbued with all the attendant safety and security concerns. The method of the present invention provides for an improved and safer method of blasting employing a highly confined combustion reaction of a flammable vapor instead of conventional explosives currently used.

A two-stage energy dissipation type shed tunnel support structure connected by a principle of Dougong and a design method thereof are provided. The two-stage energy dissipation type shed tunnel support structure includes a Dougong joint domain, crossbeams and columns. The Dougong joint domain includes section steel members, wavy-wall cylindrical elastoplastic buffers, U-shaped sliding connecting troughs and high-strength bolts. Multiple layers of the section steel members are orthogonally stacked to form a Dougong shape, the wavy-wall cylindrical elastoplastic buffers are arranged between adjacent layers of the section steel members, and the U-shaped sliding connecting troughs are arranged at upper and lower ends of the wavy-wall cylindrical elastoplastic buffers, which realizes a connection between the wavy-wall cylindrical elastoplastic buffers and a section steel in two orthogonal directions. Under an impact of small energy rockfalls, an elastic deformation of the Dougong joint domain is used to achieve a buffering.

Disclosed are a method and system for measuring and computing energy distribution in the process of intercepting a rockfall by a combination of a pine or cypress wood and an artificial structure. The amount of rockfall energy that the pine or cypress wood is capable of intercepting, together with the interception energy of the artificial structure in the process of jointly intercepting the movement of the rockfall in conjunction with the pine or cypress wood is computed based on the diameter at breast height (DBH) and average tree spacing of the pine or cypress wood as well as the length of the pine or cypress wood in the direction parallel to the slope surface and the width of the rockfall intercepting area of the pine or cypress wood.

A safety net, in particular for catching heavy loads, preferably dynamic impact bodies, in particular rocks, is formed at least to a large extent by mutually engaging net elements, and a maximum overall extension of the safety net parallel to a main extension direction of the safety net is substantially greater in an exterior region of the safety net, which in particular includes at least one outermost row of net elements, than a minimum overall extension of the safety net parallel to the main extension direction in an interior region of the safety net which differs from the exterior region.

A safety net, in particular for catching heavy loads, preferably dynamic impact bodies, in particular rocks, is formed at least to a large extent by mutually engaging net elements, and a maximum overall extension of the safety net parallel to a main extension direction of the safety net is substantially greater in an exterior region of the safety net, which in particular includes at least one outermost row of net elements, than a minimum overall extension of the safety net parallel to the main extension direction in an interior region of the safety net which differs from the exterior region.

A barrier structure for impeding erosion due to mudslides allows mud to enter through large holes in a barrier wall, and water separated from soil to drain out through smaller holes in a rear wall. An underlying reservoir can further stabilize the structure by rapidly collect water and/or mud. A backstop wall and/or an extension can be abutted to a top of the barrier wall to enhance mud collection during a mudslide. The structure can further include a penetrating passage enabling a fraction of impacting mud to flow through unimpeded, and/or a diverting wedge uphill of the apparatus diverts some impacting mud and debris while allowing a remainder thereof to pass through to the barrier wall. A plurality of the barrier structures can be installed such that mud flowing past an uphill structure impacts a downhill structure. The barrier structure can be constructed from biodegradable materials.

A barrier structure for impeding erosion due to mudslides allows mud to enter through large holes in a barrier wall, and water separated from soil to drain out through smaller holes in a rear wall. An underlying reservoir can further stabilize the structure by rapidly collect water and/or mud. A backstop wall and/or an extension can be abutted to a top of the barrier wall to enhance mud collection during a mudslide. The structure can further include a penetrating passage enabling a fraction of impacting mud to flow through unimpeded, and/or a diverting wedge uphill of the apparatus diverts some impacting mud and debris while allowing a remainder thereof to pass through to the barrier wall. A plurality of the barrier structures can be installed such that mud flowing past an uphill structure impacts a downhill structure. The barrier structure can be constructed from biodegradable materials.

An expandable modular energy-dissipation protection net unit group includes support columns each provided at each of two ends of each support column with a first horizontal longitudinal rotation reversing device on the left side, a second horizontal longitudinal rotation reversing device on the right side and a transverse rotation reversing device on the bottom; a transverse endless support rope, a longitudinal endless support rope and connectors. The transverse endless support rope is wound on the transverse rotation reversing device. The longitudinal endless support rope is wound on the first horizontal longitudinal rotation reversing device and the second horizontal longitudinal rotation reversing device adjacent. A metal net panel is tied by the plurality of connecting members and hung on the transverse endless support rope and the longitudinal endless support rope.

A longitudinal element produced with a core made of high-strength fibers and at least one metal casing, preferably steel, surrounding this core. In this way, there is the significant advantage that these high-strength fibers, which are very lightweight in relation to their strength, are protected in a number of ways, namely against humidity, moisture, UV light and other environmental influences. In addition, the metal casing provides the fibers with protection against transverse loads. In this way, all the high-strength properties of the traction or suspension means are maintained over a sustained period.

A two-stage energy dissipation type shed tunnel support structure connected by a principle of Dougong and a design method thereof are provided. The two-stage energy dissipation type shed tunnel support structure includes a Dougong joint domain, crossbeams and columns. The Dougong joint domain includes section steel members, wavy-wall cylindrical elastoplastic buffers, U-shaped sliding connecting troughs and high-strength bolts. Multiple layers of the section steel members are orthogonally stacked to form a Dougong shape, the wavy-wall cylindrical elastoplastic buffers are arranged between adjacent layers of the section steel members, and the U-shaped sliding connecting troughs are arranged at upper and lower ends of the wavy-wall cylindrical elastoplastic buffers, which realizes a connection between the wavy-wall cylindrical elastoplastic buffers and a section steel in two orthogonal directions. Under an impact of small energy rockfalls, an elastic deformation of the Dougong joint domain is used to achieve a buffering.