RU2016160C1 - Method of mud stream bed regulation - Google Patents

Abstract

FIELD: hydraulic engineering structures construction. SUBSTANCE: to regulate mud stream bed they carry out preparation of odd sites 3 and even sites 4 and installation of mud stream catching structures 5 on each odd site 3. Erosion products 8 are delayed in head races of mud stream catching structures 5. After full or partial filling of structures 5 head races with erosion products, odd sites 3 of mud stream catching structures are dismantled and erected on even sites 4. Each time before realizing the procedures they exercise erosion products, stored above odd and even sites earlier, passing down. EFFECT: method increases safety of mud stream potentially dangerous areas. 7 cl, 10 dwg

Description

 The invention relates to methods for regulating a mudflow channel using hydraulic structures and can be used on mudflow streams and their tributaries to prevent the occurrence of catastrophic mudflows.

 The aim of the invention is to increase the efficiency of work by preventing the formation of catastrophic mudflows by ensuring the movement of erosion products along the slope of the mudflow channel under conditions of limiting their speed.

 The goal is achieved by the fact that according to the method of regulating the mudflow channel, which includes the preparation of sections, the construction of a cascade of mud-collection structures with shutoff elements in odd sections, the complete or partial introduction of erosion products of upper pools of mud-collecting structures in odd gauges, and the construction of a new cascade of mud-catching structures with shutoff elements in even sections, after installing mud removal structures in even evenings, mud removal structures in odd alignments are dismantled, and after full or h The erosion of the upper pools of the mudflow structures in the even sections is dismantled, and in the odd sections they are erected, and before the start of work, for each rearrangement of the clay collection structures through the plant’s sections, the erosion products accumulated above them are passed through earlier.

 Figure 1 shows the mudflow channel and its tributaries in plan, the location of the sections of the installation of mud-collecting structures and the grouping of mud-collecting structures in cascades; figure 2 - shows the mudflow channel (fragment), a longitudinal section, mudflow structures installed in odd alignments; figure 3 is the same, the upper pool of the mudflow structures in the odd sections brought in by erosion products of rocks displaced by the next mudflow; figure 4 - the same, debris removal facilities are dismantled in odd sections, installed in even sections, in odd sections, large fractions of erosion products disassembled from through-flow dedusting structures were disassembled; figure 5 is the same, the upper pool of mudflow structures in even sections is brought in by erosion products, erosion products accumulated above odd sections are carried away by the next mudflow; in FIG. 6 - the same, mud removal structures are dismantled in even sections, installed in odd sections; Fig.7 is a through cable debris removal structure (fragment), installed in the upper section of the cascade; on Fig - the same installed in the lower section of the cascade; figure 9 shows the installation of a de-catching structure in front of a section of a mudflow channel with an increased slope, a longitudinal section; figure 10 - installation of mudflow structures in front of the canyon, plan.

 The method of regulation of the mudflow channel is as follows.

 On the mudflow channel 1 (or on its tributary 2), odd 3 and even 4 sections of the installation of mud collecting structures 5 with locking bodies are planned. Structures 5 in sections 3 (or 4) can be grouped into cascades 6 (along the mudflow channel 1, along its tributaries 2) or can be grouped into a series of cascades 6 along the main channel 1 or its tributary 2 (Fig. 1).

 Then the odd sections 3 are prepared for the installation of transverse mud-collecting structures 5. For this, depending on the type and design features of the mud-collecting structures 5, the foundation is laid out, the side supports are installed, the foundation can be erected in the form of a foundation, etc.

 In the prepared gauges 3, transverse mudflow structures 5 are erected in the form of deaf dams (from reinforced concrete, concrete, stone sketches, etc.) or in the form of through structures (cable dams, dams from prefabricated reinforced concrete with a cellular structure, dams from recycled tires, etc. P. ). End-to-end mud removal facilities 5 work more efficiently. They, with high reliability of operation, have low cost, low laboriousness of construction, can be erected in hard-to-reach sections 3, 4 in a short time. The proposed method involves the use of structures 5 in the form of blind dams in the presence of previously constructed blind dams in mudflow channels 1, 2, in the case of economic feasibility of the construction of deaf dams from local building materials, etc.

 As a result of the installation of mud-collecting structures 5, tanks 7 are received in their upper pools, which can receive large volumes of products of rock erosion 8, which are moved by each passing mudflow to the underlying marks.

 In the case of installing through mudflow structures 5, the latter additionally suppress the kinetic energy of passing mudflows (both when flowing around facilities 5 and in their upper pool, which is a water well for flow) and thereby limiting the speed of mudflows and their transporting ability.

 Compared to deaf structures, through dynamic mud collecting structures 5 are subject to many times smaller dynamic loads from mudflows, since they provide an increase in the interaction time between structures and mudflows. This allows you to significantly facilitate their supports, foundations, load-bearing elements and, therefore, reduce the cost of work.

 After the complete or partial entry of the upper pools of the mud-collection structures by 5 erosion products 8 displaced by the next mudflow, the mud-collection structures 5 in the odd sections 3 are dismantled, and 4 are erected in the lower private sections. The dismantling of structures 5 is carried out, starting from those objects in which the upper pool is more fully entered by products of erosion 8 (i.e., the dismantling of structures 5 can begin from the upper, lower sections or from the middle of the mudflow channel 1 and its tributaries 2). Moreover, in order to exclude the possibility of the formation of low-impact (catastrophic) mudflows, the dismantling of the subsequent (in time) mud removal structure 5 in the odd alignment 3 begins after the complete installation of the previous (in time) mud removal structure 5 in the even alignment 4.

 If the free volume of the tanks 7 in the upper pools of the mud-collecting structures 5 is not enough to hold in front of the protected objects 9 the total volume of products 8 of rock erosion, which can be moved by the mudflow of the calculated provision, re-installation of structures 5 can be carried out when their upper pools are partially filled with erosion products 8, without waiting for a full fill.

 If it is necessary to speed up the work, for example, after passing mudflow, which entails a large number of erosion products 8, they can simultaneously carry out the process of installing several mud removal structures 5 in even sections 4, and then dismantle structures 5 in overlying odd sections 3.

 After installing mud removal structures in even sections 4 and dismantling structures 5 in odd sections 3, measures are taken to ensure the passage of erosion products 8 (accumulated during the operation of structures 5 in sections 3) through odd sections 3 down the mudflow channel 1, 2. For this, they can dismantle blockages from large stones formed near structures 5 from the side of their upstream in sections 3 (in the case of using through structures 5), for example, with bulldozers 10 (Fig. 4), dismantling the remnants of deaf dams 5 in thieves 3 after the ablation of a part of erosion products 8 down the mudflow channel 1, 2 by the next mudflow.

 After the erosion products 8 of the upper pools of the mud removal structures 5 are entered in even sections 4, these structures are dismantled, and 3 are erected in the upstream odd sections (by analogy with the previous rearrangement of structures 5 from odd sections 3 to even sections 4).

 During the relocation of mudflow structures, 5 (from even 4 to odd 3 sections) mudflows and flood flows transfer erosion products 8, previously accumulated in the upper pools of structures located in odd sections 3, down mudflow channel 1, 2 through these sections. The flow at the same time, eroding erosion products 8, loses kinetic energy. The extinguishing of the kinetic energy of mudflow is also facilitated by structures 5 installed in even sections.

 Thus, as a result of a wave-like rearrangement of structures 5, erosion products 8 are moved by mudflows along the slope of the mudflow channel 1,2 past protected objects 9 under conditions of speed limits.

 In the case of using through mudflow structures 5, the size of holes 11 through them is reduced along the slope of the mudflow channel 1.2 in each cascade of 6 structures 5 (Fig.7, 8). This makes it possible to reduce the dynamic impact of mudflow on mud collecting structures 5, since overlying through structures 5 ensure that only large fractions of erosion products 8 are retained at the initial instant of time (and they are deposited in the upper pool of structures 5), and then a dam is formed from the through the construction of 5 and large fractions of erosion products 8 ensures the retention of parts of small fractions of erosion products 8, which are transported by mudflows and floods. The 6 structures 5 lying in cascade 6 provide for the retention of already smaller fractions of erosion products 8 transported by mudflows in the initial period of mudflow.

 Along the length of the mudflow channel 1, 2, a series of cascades of 6 mud collecting structures 5 can be erected, and if in the mudflow channel 1,2 along its length it is not expected volleys of heterogeneous mudflow fractional composition, one cascade is established along mudflow channel 1 (or 2) 6 structures 5. If a mudflow of inhomogeneous mudflow, for example, from an unregulated lateral tributary 2, is expected in a mudflow channel, for example, 1 (Fig. 1), then an additional cascade of 6 structures 5 for dispersal over time is installed behind this inflow silts of dynamic effect of mudflow on structures 5 in the main mudflow channel 1. If tributary 2 is also regulated by a cascade of 6 through mudflow structures 5, then the linear dimensions of the through holes 11 in the last even (or odd) structure 5 in cascade 6 on tributary 2 can be assigned several larger (by 10-20%) than the corresponding linear dimensions of the openings 11 of the throughness of the underlying even (or odd) structure 5 in the main mudflow channel 1. This also ensures a decrease in the dynamic impact of mudflows from the regulated mudflow tributary 2, to the underlying mud collecting structures 5 in the main mudflow channel 1.

 Each lying even (or odd 3) target 4 of the mudflow installation 5 is selected in the section of the mudflow channel 1.2, the bottom mark 12 of which (in the unregulated state) is lower than the bottom mark 12 of the mudflow channel 1.2 (in the unregulated state) in the overlying odd ( or even 4) section 3 by an amount determined from the condition Δ ≥ H, where N is the height of the mud collecting structure 5 in the even (or odd 3) section 4 of the installation. Fulfillment of this condition ensures the complete downward movement of 1.2 erosion products 8 downstream of the mudflow, accumulated earlier in odd (or even 4) sections 3 of the installation of mud collecting structures 5 (after their dismantling). If we take Δ <N, then the erosion products 8 previously accumulated above the odd (or even 4) sections 3 cannot be completely moved by mudflows through these sections 3 (or 4), which complicates the process of rearrangement of structures 5, reduces the effectiveness of the proposed regulation method mudflow channel, since the free volume of useful tanks 7 immediately after the rearrangement of structures 5 is partially filled with erosion products 8 (figure 2).

 Valves 3.4 installation of mud-collecting structures 5 can choose in front of sections of the mudflow channel 1.2 with increased slopes 13 (Fig.9). This ensures the creation in the upper pools of structures of 5 tanks 7 of the largest volume (with equal costs for the construction of structures 5) for the reception and accumulation of erosion products 8, transported by mudflows and floods.

 Valves 3.4 installation of mud-collecting structures 5 can choose in front of canyons 14 (figure 10). This ensures the creation of large useful tanks 7 for receiving and accumulating erosion products 8 with relatively small spans covered by structures 5 and, accordingly, with a minimum cost of structures 5 (since, as a rule, sections of the mudflow channel 1.2 with increased slopes begin before the start of canyon 14 )

 Mudflow structures 5 can be of collapsible design, and can also be unified according to overlapping spans and differences. This provides a quick reinstallation of structures 5 from odd sections 3 to even sections 4 and vice versa.

 The locking bodies of the mud collecting structures 5 can be calculated by the service life only for the maximum possible period of reinstallation of structures (without the adoption of safety factors). This allows you to perform structures 5 from inexpensive structural materials, to exclude the bulk of the dismantling of structures 5 in sections 3.4. So, for example, if 5 cable dams are used as mudflow structures, their dismantling is reduced to dumping their upper catenary belts from the side anchor supports. Dumped dams do not interfere with the passage of mudflow through the target of their installation; after a calculated time period, their material is destroyed, for example, corroded, which prevents environmental pollution of the mudflow channel by building structures.

 An example of a specific implementation.

 It is necessary to regulate the mudflow channel in the Design Bureau of the Autonomous Soviet Socialist Republic in order to prevent the formation of catastrophic mudflows and to protect from their impact the economic facilities located in the selenium canyon and on the removal cone. The cost of regulation of the mudflow channel should be minimal, the reliability of regulation and protection of objects should be high.

 The regulation of the mudflow channel is carried out according to the claimed method.

 On the mudflow channel of AB and on its tributaries ZhZ, DE and IK (Fig. 1), the odd and even sections of the installation of mud collecting structures are outlined. Although the VG inflow is a mudflow generator and a supplier of large volumes of mudflows of a heterogeneous fractional composition, it is extremely difficult to carry out work, therefore, it is not planned to regulate it.

 The odd (or even) mudflow structures are grouped into cascades: one on the tributaries of the ZhZ, DE and IK and two cascades on the main mudflow channel of the AB, and the second (underlying) cascade is located after an unregulated inflow of SH.

 Rigid dams are used as self-catching structures. In the sections of their installation, the planning of the base is carried out - the expansion of coarse fragments of rocks and boulders. On the banks (or walls) of the mudflow channel, anchor supports are performed, for example, by drilling in a rock with subsequent installation in the well and concreting the well with an anchor.

 A cable dam is installed without a nodal and water-bearing parts. To eliminate the folding of the dam (vertically) between the upper catenary belt and the lower longitudinal cables (or lower catenary belt), spacers can be installed, for example, from steel pipes with a diameter of 250-300 mm at a distance of 3-4 m from each other.

 The catenar belts and the cable network of dams can be made of steel ropes of the type ТК 7х37 = 259 wires with a metal core. Loads in cable-stayed systems can be determined by known methods (see, for example, Recommendations on the static calculation of soft membrane dams. / Comp. B.I. Sergeev, V. L. Bondarenko, V. A. Volosukhin, V. M. Kompaniyets; Yuzh. Scientific Research Institute of Hydraulic Engineering and Land Reclamation - Novocherkassk, 1977, p. 35; Designer's Guide to Industrial, Residential, and Public Buildings and Structures: Settlement and Theoretical, book 1. / Under the editorship of A.A. Umansky. - M.: Publishing House in literature on building., 1972, p. 579-599). Based on the calculated loads, the permissible normal stress in the material of the cables, the required cable diameters of the catenary belts and grids are determined.

 The height of the cable dams is assigned in the range from 2 to 3.5 m, the spans they overlap are from 4 to 25 m. Dams are installed at the end of horizontal sections in mudflow channels in front of sections with increased slopes. The dimensions of the grids from which the dams are made, depending on the particle size distribution of rock erosion products moved by mudflows, are assigned from (1.5 x 1.5 m) - (2.0 x 2.0 m) in the upper cascade dams to (0.15 x 0.15 m) - (0.3 x 0.3 m) in the lower structures in cascades.

 The cable-driven de-catching structures made in this way, rearranged along the mudflow channel and its tributaries according to the invention, prevent the formation of catastrophic mudflows by ensuring the movement of erosion products along the slope of the mudflow channel under conditions of speed limits. This technical solution during implementation does not require large capital expenditures, provides reliable deprotection of facilities.

 Using the proposed method will provide a simplification of the work, reducing their cost, which is achieved through the use of through collapsible collapsible dedusting structures of low cost, including without ponuros and water holes. The cost of implementing the inventive method is 10 times or more lower than the cost of implementing the basic method (installation of a cascade of permanent in terms of mud removal structures with subsequent expansion of dams). Using the claimed method for regulating the mudflow channel allows to prevent the formation of catastrophic mudflows by ensuring the movement of erosion products along the slope of the mudflow channel under the conditions of limiting their speeds during the interaction of mudflows with mudflow structures. High reliability of mudflow protection is provided. It is possible to use industrial waste to deal with mudflows, for example recycled tires for pneumatic tires.

Claims (7)

 1. METHOD FOR REGULATING A REDUCED BEDROOM, including preparation of sections, construction of a cascade of mud-catching structures with locking bodies in odd sections, full or partial introduction of erosion products of upper pools of mud-collecting structures in odd sections, and the construction of a new cascade of mud-catching structures in odd sections, that, in order to increase the efficiency of work by preventing the formation of catastrophic mudflows by ensuring the movement of erosion products along l the slope of the mudflow channel under the conditions of limiting the speed of their movement, after installing mud removal structures in even sections, mud removal structures in odd sections are dismantled, and after the erosion products have completely or partially entered the upper pools of mudflow structures in even sections, these structures are dismantled, and in odd sections moreover, before the commencement of work on each rearrangement of the mud-collecting structures through the plant’s gates, the erosion products accumulated above them are passed through it.  2. The method according to claim 1, characterized in that the sections of the installation of mud collecting structures are selected in front of sections of the mudflow channel with increased slopes.  3. The method according to PP. 1 and 2, characterized in that the sections of the installation of mud removal structures are chosen in front of the canyons.  4. The method according to PP. 1-3, characterized in that through structures are used as mud collecting structures, and the size of through holes in mud collecting facilities in the cascade is reduced along the slope of the mudflow channel.  5. The method according to PP. 1 and 4, characterized in that the de-catching structures perform a collapsible structure.  6. The method according to PP. 1 - 5, characterized in that a series of cascades of mud collecting structures are erected along the length of the mudflow channel.  7. The method according to PP. 1 - 6, characterized in that the locking bodies of the mud-collecting structures are made of materials with a service life not exceeding the maximum possible permutation period for each mud-collecting structure in each site.

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