CN214585417U

CN214585417U - Experimental device for simulating and monitoring multi-source all-terrain movement of debris flow

Info

Publication number: CN214585417U
Application number: CN202120770288.6U
Authority: CN
Inventors: 叶天浩; 王光进; 蔚美娇; 康富淇; 曹恒亮; 何明渝; 宋宁思; 李源源; 林水泉; 赵冰; 艾啸韬; 崔博; 陈志斌; 胡航; 尤耿明
Original assignee: Kunming University of Science and Technology
Current assignee: Kunming University of Science and Technology
Priority date: 2021-04-15
Filing date: 2021-04-15
Publication date: 2021-11-02
Anticipated expiration: 2031-04-15

Abstract

The utility model relates to an experimental apparatus of simulation and monitoring many sources of debris flow full topography motion belongs to geotechnical engineering experimental apparatus technical field. The device comprises an animal source supply device, an on-way object source supply device, a multi-degree-of-freedom terrain simulation device, a rainfall simulation device, a debris flow motion monitoring device and the like. The device comprises a material source supply device, a multi-degree-of-freedom terrain simulation device, a rainfall simulation device, a support device and a debris flow motion monitoring device, wherein the material source supply device is used for providing required material sources for experiments, the multi-degree-of-freedom terrain simulation device is used for simulating different terrain conditions, the rainfall simulation device is used for simulating rainfall working conditions, the support device is used for supporting the rainfall simulation device and the hanging monitoring equipment, and the debris flow motion monitoring device is used for completing the whole process research of debris flow motion. The utility model discloses can simulate the research under rainfall, thing source supply, erosion deposit, complicated topography condition, the complete process of mud-rock flow evolution to through automatic monitoring facilities record material exchange, velocity of flow change, flow acceleration isoparametric, realize the research to the process of causing a disaster, prediction mud-rock flow scale and harm range.

Description

Experimental device for simulating and monitoring multi-source all-terrain movement of debris flow

Technical Field

The utility model relates to a simulation and monitoring experimental apparatus of the all-terrain motion of many sources of debris flow, more specifically say, are a debris flow experiment analogue means, belong to geotechnical engineering experimental apparatus technical field.

Background

The debris flow is a special flood flow which is caused by rainstorm, snowstorm or other natural disasters and flows fast with a large amount of silt and rock masses under proper terrain conditions, and has the characteristics of sudden outbreak, high flow speed, large flow, large material capacity, strong destructive power and the like. Debris flow is often accompanied by mountainous flood. The difference between the flood and the common flood is that the flood contains enough solid debris such as silt, stone and the like, the volume content of the solid debris is at least 15 percent and can reach about 80 percent at most, and therefore, the flood is more destructive than the flood.

The indoor model test is widely applied as an important engineering science research means, can effectively utilize limited manpower, material resources and time to carry out simulation research on geological disasters such as debris flow, and the like, reveals and reflects the essence of the phenomenon through the model test, and summarizes the conclusion law theory to solve the practical problem. The debris flow simulation test is an important means for researching the characteristics of debris flow disasters by simulating a series of processes such as formation, development, movement, accumulation and the like of the debris flow. At present, a straight inclined organic glass groove is mostly used for simulating a trench bed in a debris flow indoor simulation test at home and abroad, a debris flow starting test is carried out through water tank drainage simulation confluence or a rainfall simulation device, and characteristic parameters such as soil body water potential, water content, pore water pressure, temperature and the like in the test process are monitored in real time.

The problems that exist are that:

(1) the slope adjustment is inconvenient, and most of equipment cannot flexibly adjust the slope of the groove body in a segmented manner;

(2) the contour dimension of the model groove is fixed, only the debris flow with specific terrain and specific scale can be simulated, the straight inclined groove can not simulate tortuous valley, large-fall terrain, open accumulation area and the like, the universality and universality are poor, and the utilization rate of the model groove is reduced;

(3) the test simulation condition is single, the comparison test of different natural conditions of different sources can not be carried out, and the simulation efficiency is low.

(4) The material source supply is single, most of tests enable slurry to be flushed out of the slurry tank and move along the mold groove, so that the debris flow is simulated, the supply of solid materials in the debris flow advancing process is ignored, and a certain difference exists between the supply and the real debris flow movement rule.

(5) The roughness of the groove bottom is increased by cement mortar and the like to simulate a natural channel, the forming takes long time, the replacement is not easy, and the simulation experiment under different surface conditions is difficult to be carried out quickly.

Disclosure of Invention

Problem and not enough to above-mentioned prior art exist, the utility model provides a simulation and monitoring experimental apparatus of the full topography motion in many sources of mud-rock flow, this device can be used to laboratory mud-rock flow indoor simulation test.

The utility model adopts the technical proposal that:

an experimental device for simulating and monitoring multi-source all-terrain movement of debris flow comprises an animal source supply device, an on-way source supply device, a multi-degree-of-freedom terrain simulation device, a rainfall simulation device, a debris flow movement monitoring device and a support device;

the device comprises a multi-degree-of-freedom terrain simulator, an animal starting source supply device, a support device, a rainfall simulator, a debris flow motion monitoring device and a control device, wherein the animal starting source supply device is positioned at the rear end of the multi-degree-of-freedom terrain simulator;

the on-way object source supply device comprises a material supply groove 43, a pulley block 44, a lifting system 45, a hydraulic system 46 and a base 47, wherein the lifting system 45 and the hydraulic system 46 are arranged between the base 47 and the pulley block 44, the material supply groove 43 is arranged on the pulley block 44, and a plurality of groups of on-way object source supply devices are arranged on one side of the multi-degree-of-freedom terrain simulation device at equal intervals;

the multi-degree-of-freedom terrain simulation device comprises a slope sensing system 48, a slope data acquisition and transmission system 49, slope supporting rods 19, a slope supporting rod controller 20, a slope angle frame 21, a slope angle frame controller 22, a terrain data transmission line 25, a terrain regulator 26, a slope angle data transmission line 27, a slope angle regulator 28, a computer 29, a slurry recycling box 50 and an electronic scale 51, wherein the slope sensing system 48 is of a continuous complete membrane structure and is supported by a plurality of slope supporting rods 19 which are uniformly and densely arranged, the lower ends of the slope supporting rods 19 are connected with the slope data acquisition and transmission system 49, the slope supporting rod controller 20 is positioned below the slope data acquisition and transmission system 49, the slope supporting rod controller 20 is fixed on the slope angle frame 21, the slope angle frame 21 is fixed on the upper part of the slope angle frame controller 22, the slope angle frame 21 and the slope angle frame controller 22 are provided with a plurality of groups, and the slope supporting rod controller 20 is sequentially connected with the terrain data transmission line 25, the slope angle frame controller, A terrain regulator 26 and a computer 29, wherein the inclination angle frame controller 22 is connected with an inclination angle data transmission line 27, an inclination angle regulator 28 and the computer 29 in sequence;

the rainfall simulation device comprises a water storage tank II 35, a water pump II 34, a pressure gauge 33, a rainfall main pipe 36, rainfall distribution pipes 37 and rainfall sprayers 38 which are sequentially connected, wherein an exhaust valve 32 and a flowmeter II 31 are installed on the pressure gauge 33, a valve II 30 is arranged on the rainfall main pipe 36, the rainfall main pipe 36 is connected with the rainfall distribution pipes 37 arranged on a rainfall water pipe support 39, and a plurality of rainfall sprayers 38 are uniformly distributed on each rainfall distribution pipe 37;

the debris flow movement monitoring device comprises an equipment hanger 40, a high-speed camera 41 and a multi-parameter acquisition and transmission system 42, wherein the high-speed camera 41 is mounted at the tail end of the equipment hanger 40, and the multi-parameter acquisition and transmission system 42 is mounted at the lower edge of a telescopic boom of the equipment hanger 40.

Specifically, play animal source feeding device and include storage water tank I1, water pump I2, water pipe 3, valve I4, flowmeter I5, feeder hopper 6, stirring storehouse 7, ultrasonic wave slurry concentration measuring instrument 12, mud export 13, sample connection 14, flowmeter 15, storage water tank I1, water pump I2, water pipe 3 concatenates, valve I4, flowmeter I5 sets up on water pipe 3, inside water pipe 3 end stretched into stirring storehouse 7 by the top, the end of feeder hopper 6 stretches into stirring storehouse 7 by the top in, mud export 13 and sample connection 14 are located stirring storehouse 7 lower part, stirring storehouse 7 monolithic stationary phase is on connecting rod 16, connecting rod 16 bottom installation axis of rotation 17, axis of rotation 17 fixed connection is on axis of rotation controller 18, ultrasonic wave slurry concentration measuring instrument 12 is installed on stirring storehouse 7 outer wall and is located mud export 13 top.

Specifically, stirring storehouse 7 includes hopper 8, action wheel 9, follows driving wheel 10, (mixing) shaft 111, stirring leaf 112, rotational viscometer 52, and hopper 8 evenly arranges that the extension is driven by rivers at action wheel 9, and the action wheel 9 of vertical placing meshes with the driven driving wheel 10 of horizontal placement, connects in the upper end of (mixing) shaft 111 from driving wheel 10, and stirring leaf 112 is connected in the lower extreme of (mixing) shaft 111, and rotational viscometer 52 installs on stirring storehouse 7 bottom plate.

Specifically, the slope surface support rod 19 comprises a ball 191, a universal joint 192, a rotating shaft 193 and a hydraulic lifting device 194, the top of the ball 191 is connected with the slope surface sensing system 48 through a snap fastener 195, the ball 191 is sleeved in the upper end of the universal joint 192, the rotating shaft 193 is installed at the lower end of the universal joint 192, and the rotating shaft 193 is fixed on the hydraulic lifting device 194.

Specifically, the slope sensing system 48 comprises a simulated earth surface membrane material 481, an electric signal transmission membrane 482, a pressure sensitive membrane 483, an insulating protective membrane 484 and an electric wire 485, wherein the simulated earth surface membrane material 481, the electric signal transmission membrane 482, the pressure sensitive membrane 483 and the insulating protective membrane 484 are attached from top to bottom, the electric wire 485 is communicated with the electric signal transmission membrane 482, the roughness of the simulated earth surface membrane material 481 is adjusted according to the actual vegetation coverage rate of the earth surface, and the lower part of the insulating protective membrane 484 is connected with a slope supporting rod 19 through a snap fastener 195.

Specifically, the lifting system 45 includes a lifting platform 451, a slide rail 452, a plurality of sets of scissor arms 453 and connecting rivets 454, the slide rail 452 is embedded inside the lifting platform 451, a groove is formed in the lower surface of the lifting platform 451, the connecting rivets 454 rivet the arm levers of the plurality of sets of scissor arms 453, the plurality of sets of scissor arms 453 are parallel to the slide rail 452, the upper ends of the plurality of sets of scissor arms 453 are fixed to the lower surfaces of two sides of the lifting platform 451, and the lower ends of the plurality of sets of scissor arms 453 are fixed to the upper surfaces of two sides of the hydraulic system 46.

Specifically, the hydraulic system 46 includes a top pulley 461, a hydraulic rod 462, a bottom rotating shaft 463 and a power control system 464, wherein the top pulley 461 is fixed on the top of the hydraulic rod 462, the hydraulic rod 462 is slotted into the lifting platform 451 from the lower surface of the lifting platform 451, the top pulley 461 can slide in the sliding rail 452 along the rail, the bottom rotating shaft 463 is hinged to the bottom of the hydraulic rod 462 and is rotatably connected to the power control system 464, and the lower ends of the plurality of sets of scissor arms 453 are fixed on two sides of the power control system 464.

Specifically, the pulley block 44 includes a front pulley set and a rear pulley set, the front pulley set includes a front wheel, a wheel shaft 441, a motor 442, and a bearing support 443, the two front wheels are fixed at two ends of the wheel shaft 441, the wheel shaft passes through the bearing support 443 and can rotate freely, the bearing support 443 is fixed on the lifting platform 451, the motor 442 is connected to the middle of the wheel shaft 441, the front end of the material supply groove 43 is placed on the front wheel, and the rear pulley set includes four rotating wheels connected to the rear end of the bottom of the material supply groove 43.

Preferably, the two sides of the multi-degree-of-freedom terrain simulator are provided with on-way object source supply devices.

The utility model has the advantages that:

(1) the device can be used for simulating debris flow under various different terrain conditions in a laboratory, and has the advantages of wide application range and high reuse rate;

(2) the device adopts an automatic closed slurry stirring system, and is energy-saving and environment-friendly;

(3) the device can be used for simulating debris flow under various different source supply conditions and rainfall conditions in a laboratory, and is more practical;

(4) the device can be used for matching different simulated earth surface membrane materials according to the earth surface conditions of different research objects. The replacement is convenient, the use is rapid, and the labor intensity of manual laying is reduced;

(5) the slope sensing system of the device monitors the whole processes of debris flow generation, development and accumulation in real time, and collects data accurately and efficiently.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic view of the structure of the source proportioning device of the present invention;

FIG. 3 is a schematic structural view of the multi-degree-of-freedom terrain simulator of the present invention;

FIG. 4 is a schematic view of the slope supporting rod of the present invention;

FIG. 5 is a schematic plane structure of the on-way object source supply device of the present invention;

fig. 6 is a schematic structural view of the lifting system of the present invention;

FIG. 7 is a schematic view of the pulley block structure of the on-way object supply device of the present invention;

fig. 8 is a schematic structural view of the slope sensing system of the present invention.

The reference numbers in the figures are: 1-water storage tank I, 2-water pump I, 3-water pipe, 4-valve I, 5-flowmeter I, 6-feed hopper, 7-stirring bin, 8-water hopper, 9-driving wheel, 10-driven wheel, 11-stirrer, 12-ultrasonic slurry concentration measuring instrument, 13-slurry outlet, 14-sampling port, 15-flowmeter, 16-connecting rod, 17-rotating shaft, 18-rotating shaft controller, 19-slope supporting rod, 20-slope supporting rod controller, 21-inclination frame, 22-inclination frame controller, 23-rotation angle data transmission line, 24-rotation angle regulator, 25-terrain data transmission line, 26-terrain regulator, 27-inclination angle data transmission line, 28-inclination angle regulator, 29-computer, 30-valve II, 31-flowmeter II, 32-exhaust valve, 33-pressure gauge, 34-water pump II, 35-water storage tank II, 36-rainfall main water pipe, and, 37-rainfall water diversion pipe, 38-rainfall spray head, 39-rainfall water pipe support, 40-equipment hanger, 41-high speed camera, 42-multi-parameter acquisition and transmission system, 43-material supply tank, 44-pulley block, 45-lifting system, 46-hydraulic system, 47-base, 48-slope sensing system, 49-slope data acquisition and transmission system, 50-slurry recovery tank, 51-electronic scale, 52-rotary viscometer, ball-191, universal joint-192, rotating shaft-193, hydraulic lifting device-194, snap button-195, surface imitation film-481, electric signal conduction film-482, pressure sensitive film-483, insulation protection film-484, wire-485, lifting platform-451, slide rail-452, multiple sets of shearing fork arms-453, connecting rivet-454, top pulley-461, hydraulic rod-462, bottom rotating shaft-463, power control system-464, wheel shaft-441, bottom rotating shaft-462, power control system-464, Motor 442, bearing support 443.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the following detailed description.

In the description of the present invention, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "lateral", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1: as shown in fig. 1-8, an experimental device for simulating and monitoring multi-source all-terrain movement of debris flow comprises an animal source supply device, an on-way source supply device, a multi-degree-of-freedom terrain simulation device, a rainfall simulation device, a debris flow movement monitoring device and a support device;

Further, play animal source feeding device and include storage water tank I1, water pump I2, water pipe 3, valve I4, flowmeter I5, feeder hopper 6, stirring storehouse 7, ultrasonic wave slurry concentration measurement appearance 12, mud export 13, sample connection 14, flowmeter 15, storage water tank I1, water pump I2, water pipe 3 concatenates, valve I4, flowmeter I5 sets up on water pipe 3, inside water pipe 3 end stretched into stirring storehouse 7 by the top, the end of feeder hopper 6 stretches into stirring storehouse 7 by the top in, mud export 13 and sample connection 14 are located stirring storehouse 7 lower part, stirring storehouse 7 monolithic stationary ladle is on connecting rod 16, connecting rod 16 bottom installation axis of rotation 17, axis of rotation 17 fixed connection is on axis of rotation controller 18, ultrasonic wave slurry concentration measurement appearance 12 is installed on stirring storehouse 7 outer wall and is located mud export 13 top.

Further, stirring storehouse 7 includes hopper 8, action wheel 9, from driving wheel 10, (mixing) shaft 111, stirring leaf 112, rotational viscometer 52, hopper 8 evenly arranges and extends at action wheel 9 and is driven by rivers, the action wheel 9 of vertical placing meshes with the driven wheel 10 of level placement, connect the upper end at (mixing) shaft 111 from driving wheel 10, stirring leaf 112 is connected at the lower extreme of (mixing) shaft 111, action wheel 9 drives from driving wheel 10 and rotates, and then drive (mixing) shaft 111 and stirring leaf 112 and rotate and stir, rotational viscometer 52 installs on stirring storehouse 7 bottom plate. Water flow is injected into the stirring bin 7 from the upper end through the water pipe 3 and drives the water bucket 8, the water bucket 8 drives the driving wheel 9 and the driven wheel 10 to rotate, the driven wheel 10 drives the stirrer 11 to stir slurry, and the inclination angle of the stirring bin 7 is controlled by the rotating shaft controller 18.

Further, the slope surface support rod 19 comprises a ball 191, a universal joint 192, a rotating shaft 193 and a hydraulic lifting device 194, the top of the ball 191 is connected with the slope surface sensing system 48 through a snap fastener 195, the ball 191 is sleeved in the upper end of the universal joint 192, the rotating shaft 193 is installed at the lower end of the universal joint 192, and the rotating shaft 193 is fixed on the hydraulic lifting device 194.

Further, the slope sensing system 48 comprises a simulated earth surface membrane 481, an electric signal transmission membrane 482, a pressure sensitive membrane 483, an insulation protective membrane 484 and an electric wire 485, wherein the simulated earth surface membrane 481, the electric signal transmission membrane 482, the pressure sensitive membrane 483 and the insulation protective membrane 484 are attached from top to bottom, the electric wire 485 is communicated with the electric signal transmission membrane 482, the roughness of the simulated earth surface membrane 481 is adjusted according to the actual vegetation coverage rate of the earth surface, the lower part of the insulation protective membrane 484 is connected with a slope supporting rod 19 through snap buttons 195, and the simulated earth surface membrane 481 continuously deforms along with the slope supporting rod 19 so as to simulate real terrain and slope.

Further, the lifting system 45 includes a lifting platform 451, a slide rail 452, a plurality of sets of scissor arms 453 and connecting rivets 454, the slide rail 452 is embedded inside the lifting platform 451, a groove is formed in the lower surface of the lifting platform 451, the connecting rivets 454 rivet the arm levers of the plurality of sets of scissor arms 453, the plurality of sets of scissor arms 453 are parallel to the slide rail 452, the upper ends of the plurality of sets of scissor arms 453 are fixed to the lower surfaces of two sides of the lifting platform 451, and the lower ends of the plurality of sets of scissor arms 453 are fixed to the upper surfaces of two sides of the hydraulic system 46.

Further, the hydraulic system 46 includes a top pulley 461, a hydraulic rod 462, a bottom rotating shaft 463, and a power control system 464, wherein the top pulley 461 is fixed on the top of the hydraulic rod 462, the hydraulic rod 462 is slotted from the lower surface of the lifting platform 451 and extends into the lifting platform 451, the top pulley 461 can slide in the sliding rail 452 along the rail, the bottom rotating shaft 463 is hinged to the bottom of the hydraulic rod 462 and is rotatably connected to the power control system 464, and the lower ends of the plurality of sets of scissor arms 453 are fixed on two sides of the power control system 464.

Further, the pulley assembly 44 includes a front pulley assembly including a front wheel, a wheel shaft 441, a motor 442, and a bearing support 443, the two front wheels are fixed at two ends of the wheel shaft 441, the wheel shaft passes through the bearing support 443 and can rotate freely, the bearing support 443 is fixed on the lifting platform 451, the motor 442 is connected to the middle of the wheel shaft 441, the front end of the material supply groove 43 is placed on the front wheel, and the rear pulley assembly includes four rotating wheels connected to the rear end of the bottom of the material supply groove 43.

Furthermore, both sides of the multi-degree-of-freedom terrain simulator are provided with on-way object source supply devices. Both sides all set up along journey thing source feeding device, can supply with the material fast for the experiment process.

The utility model discloses a theory of operation does:

(1) inputting terrain parameters into a computer 29, controlling an inclination angle frame 21 through an inclination angle regulator 28 to adjust the integral terrain inclination angle, controlling the telescopic length of each slope supporting rod 19 through a terrain regulator 26, subdividing the slope by the supporting rods through multiple degrees of freedom provided by combination of top-end balls 191, universal joints 192 and rotating shafts 193 to simulate details of terrain, and generating continuous deformation along with the simulated terrain surface membrane 481 fixed on the balls 191 through snap buttons 195 to simulate real terrain and gradient;

(2) pouring proportioned solid materials into a stirring bin 7 through a feed hopper 6, opening a valve I4 and a water pump I2, injecting water in a water storage tank I1 into the stirring bin 7 through a water pipe 3 and driving a water bucket 8, wherein the water bucket 8 drives a driving wheel 9 and a driven wheel 10 to rotate, and the driven wheel 10 drives a stirring shaft 111 and a stirring blade 112 to rotate so as to stir slurry;

(3) adjusting and calibrating the equipment hanger 40, starting the equipment high-speed camera 41 and the multi-parameter acquisition and transmission system 42 so as to record parameters such as fluid flow, flow velocity, impact force and the like, wherein the equipment hanger 40 can realize stretching and shrinking in the front, back, up and down directions relative to the slope sensing system 48, so that the whole process monitoring of the debris flow disaster simulation test is carried out;

(4) according to the characteristics of vegetation coverage of a research object and the like, the simulated earth surface film 481 with different roughness is selected, the slope sensing system 48 is started, the pressure sensitive film 483 converts collected pressure signals into electric signals, the electric signal transmission film 482 transmits data to the slope data acquisition and transmission system 49 in real time, and finally the slope data acquisition and transmission system 49 transmits the data to a computer.

(5) After the materials in the stirring bin 7 are stirred, the rotating shaft controller 18 is started to control the rotating shaft 17, the inclination angle of the stirring bin 7 is changed through the connecting rod 16, and the slurry outlet 13 is opened after the proper inclination angle is reached so that the slurry is poured out;

(6) when rainfall simulation is needed, the valve II 30 and the water pump II 34 are opened, water in the water storage tank II 35 enters the rainfall water distribution pipe 37 through the flowmeter II 31 and the rainfall main pipe 36, the opening degree of the valve II 30 is adjusted, the rainfall amount of the rainfall spray head 38 is adjusted, the water pressure is stabilized through the exhaust valve 32, and different rainfall conditions are simulated;

(7) when materials need to be added, required along-the-way replenishing materials are stacked in the material replenishing groove 43, the power control system 464 is opened to lift the hydraulic rod 462, the bottom rotating shaft 463 is adjusted to enable the top pulley 461 to slide in the sliding rail 452 so as to adjust the force application point of the hydraulic rod 462, so that the inclination angle of the lifting platform 451 is changed, meanwhile, the wheel shaft 441 is driven to rotate through the starting motor 442, the front wheels of the pulley blocks 44 fixed at the two ends of the wheel shaft 441 rotate along with the wheel shaft, the material replenishing groove 43 is pushed to the edge of the slope surface sensing system 48, the materials are further supplied into the slope surface sensing system 48, and the plurality of groups of scissor arms 453 play a role in supporting and stabilizing the lifting platform 451 during lifting.

(8) The water flow and the silt flow generated in the test process flow into the mud recovery box 50 through the slope sensing system 48, and are dried and screened for recycling.

The utility model discloses can simulate the research under rainfall, thing source supply, erosion deposit, complicated topography condition, the complete process of mud-rock flow evolution to through automatic monitoring facilities record material exchange, velocity of flow change, flow acceleration, flow resistance, total head, by momentum exchange, mud-rock flow impact force, the solid matter that erosion and deposit arouse pile up the isoparametric, realize the research to the process of causing a disaster, prediction mud-rock flow scale and harm range.

While the present invention has been described in detail with reference to the specific embodiments thereof, it is to be understood that the present invention is not limited to the embodiments described above, and that various changes and modifications may be made without departing from the spirit and scope of the present invention.

Claims

1. The utility model provides an experimental apparatus for simulation and monitoring mud-rock flow many sources all terrain movement which characterized in that: the device comprises an animal source supply device, an on-way object source supply device, a multi-degree-of-freedom terrain simulation device, a rainfall simulation device, a debris flow motion monitoring device and a support device;

the on-way object source supply device comprises a material supply groove (43), a pulley block (44), a lifting system (45), a hydraulic system (46) and a base (47), wherein the lifting system (45) and the hydraulic system (46) are installed between the base (47) and the pulley block (44), the material supply groove (43) is formed in the pulley block (44), and a plurality of groups of on-way object source supply devices are arranged on one side of the multi-degree-of-freedom terrain simulation device at equal intervals;

the multi-degree-of-freedom terrain simulation device comprises a slope sensing system (48), a slope data acquisition and transmission system (49), slope supporting rods (19), a slope supporting rod controller (20), a slope angle frame (21), a slope angle frame controller (22), a terrain data transmission line (25), a terrain regulator (26), a slope angle data transmission line (27), a slope angle regulator (28), a computer (29), a slurry recovery box (50) and an electronic scale (51), wherein the slope sensing system (48) is of a continuous complete membrane structure and is supported by a plurality of slope supporting rods (19) which are uniformly and densely arranged, the lower ends of the slope supporting rods (19) are connected with the slope data acquisition and transmission system (49), the slope supporting rod controller (20) is positioned below the slope data acquisition and transmission system (49), and the slope supporting rod controller (20) is fixed on the slope angle frame (21), the slope support rod controller (20) is sequentially connected with a terrain data transmission line (25), a terrain regulator (26) and a computer (29), and the inclination angle frame controller (22) is sequentially connected with an inclination angle data transmission line (27), an inclination angle regulator (28) and a computer (29);

the rainfall simulation device comprises a water storage tank II (35), a water pump II (34), a pressure gauge (33), a rainfall water main (36), rainfall water distribution pipes (37) and rainfall sprayers (38) which are sequentially connected, wherein an exhaust valve (32) and a flowmeter II (31) are installed on the pressure gauge (33), a valve II (30) is arranged on the rainfall water main (36), the rainfall water main (36) is connected with the rainfall water distribution pipes (37) arranged on a rainfall water pipe support (39), and a plurality of rainfall sprayers (38) are uniformly distributed on each rainfall water distribution pipe (37);

the debris flow movement monitoring device comprises an equipment hanger (40), a high-speed camera (41) and a multi-parameter acquisition and transmission system (42), wherein the high-speed camera (41) is mounted at the tail end of the equipment hanger (40), and the multi-parameter acquisition and transmission system (42) is mounted at the lower edge of a telescopic suspension arm of the equipment hanger (40).

2. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 1, wherein: the animal source supply device comprises a water storage tank I (1), a water pump I (2), a water pipe (3), a valve I (4), a flowmeter I (5), a feed hopper (6), a stirring bin (7), an ultrasonic slurry concentration measuring instrument (12), a slurry outlet (13), a sampling port (14) and a flowmeter (15), wherein the water storage tank I (1), the water pump I (2) and the water pipe (3) are connected in series, the valve I (4) and the flowmeter I (5) are arranged on the water pipe (3), the tail end of the water pipe (3) extends into the stirring bin (7) from the top, the tail end of the feed hopper (6) extends into the stirring bin (7) from the top, the slurry outlet (13) and the sampling port (14) are positioned at the lower part of the stirring bin (7), the stirring bin (7) is integrally fixed on a connecting rod (16), a rotating shaft (17) is installed at the bottom end of the connecting rod (16), and the rotating shaft (17) is fixedly connected to a rotating shaft controller (18), the ultrasonic slurry concentration measuring instrument (12) is arranged on the outer wall of the stirring bin (7) and is positioned above the slurry outlet (13).

3. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 2, wherein: stirring storehouse (7) are including hopper (8), action wheel (9), from driving wheel (10), (mixing) shaft (111), stirring leaf (112), rotational viscometer (52), hopper (8) are evenly arranged and are driven by rivers in action wheel (9) extension, the action wheel (9) of vertical placing and the meshing of the follow driving wheel (10) that the level was placed, connect the upper end at (mixing) shaft (111) from driving wheel (10), the lower extreme at (mixing) shaft (111) is connected in stirring leaf (112), rotational viscometer (52) are installed on stirring storehouse (7) bottom plate.

4. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 1, wherein: domatic bracing piece (19) are connected with domatic sensing system (48) through snap fastener (195) including ball (191), universal joint (192), pivot (193), hydraulic pressure elevating gear (194) at ball (191) top, ball (191) embolia universal joint (192) upper end, and pivot (193) are installed to universal joint (192) lower extreme, and pivot (193) are fixed on hydraulic pressure elevating gear (194).

5. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 1, wherein: the slope sensing system (48) comprises a simulated earth surface membrane material (481), an electric signal transmission membrane (482), a pressure sensitive membrane (483), an insulation protective membrane (484), an electric wire (485), the simulated earth surface membrane material (481), the electric signal transmission membrane (482), the pressure sensitive membrane (483) and the insulation protective membrane (484) are attached from top to bottom, the electric wire (485) is communicated with the electric signal transmission membrane (482), the roughness of the simulated earth surface membrane material (481) is adjusted according to the actual vegetation coverage rate of the earth surface, and the lower portion of the insulation protective membrane (484) is connected with a slope supporting rod (19) through a snap fastener (195).

6. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 1, wherein: lifting system (45) are including lift platform (451), slide rail (452), multiunit scissor arm (453), connect rivet (454), slide rail (452) are embedded inside lift platform (451), lift platform (451) lower surface fluting, connect rivet (454) with the arm pole riveting of multiunit scissor arm (453), multiunit scissor arm (453) are parallel with slide rail (452), the lower surface of lift platform (451) both sides is fixed in on multiunit scissor arm (453), the lower extreme is fixed in the upper surface of hydraulic system (46) both sides.

7. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 6, wherein: the hydraulic system (46) comprises a top end pulley (461), a hydraulic rod (462), a bottom end rotating shaft (463) and a power control system (464), wherein the top end pulley (461) is fixed at the top of the hydraulic rod (462), the hydraulic rod (462) extends into the lifting platform (451) from a groove formed in the lower surface of the lifting platform (451), the top end pulley (461) can slide in a sliding rail (452) along a rail, the bottom end rotating shaft (463) is hinged to the bottom of the hydraulic rod (462) and is rotatably connected to the power control system (464), and the lower ends of a plurality of groups of scissor arms (453) are fixed on two sides of the power control system (464).

8. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 6, wherein: the pulley block (44) comprises a front pulley block and a rear pulley block, the front pulley block comprises front wheels, a wheel shaft (441), a motor (442) and a bearing support (443), the two front wheels are fixed at two ends of the wheel shaft (441), the wheel shaft penetrates through the bearing support (443) and can freely rotate, the bearing support (443) is fixed on the lifting platform (451), the motor (442) is connected to the middle of the wheel shaft (441), the front end of the material supply groove (43) is placed on the front wheels, and the rear pulley block comprises four rotating wheels connected to the rear end of the bottom of the material supply groove (43).

9. The experimental facility for simulating and monitoring the all-terrain movement of multiple debris sources in a debris flow according to claim 1, wherein: and two sides of the multi-degree-of-freedom terrain simulation device are provided with on-way object source supply devices.