CN212228876U - Testing device for influence of natural gas hydrate decomposition on seabed slope - Google Patents

Abstract

The utility model discloses a test device for the influence of natural gas hydrate decomposition on a seabed slope, which belongs to the technical field of marine disaster research, and comprises a methane gas conveying device, a model box and a water vapor conversion device, wherein a high-permeability sand layer is laid at the bottom of the model box, a perforated pipe is uniformly laid on the high-permeability sand layer, an inclined test soil sample is laid above the perforated pipe, two ends of the perforated pipe extend out of the model box and are respectively connected with the methane gas conveying device and the water vapor conversion device, the utility model converts the natural gas hydrate in the deep sea into an actual operable controllable variable, by analyzing the action of the decomposed product of the natural gas hydrate on the seabed slope, the damage condition of the actual action is met, the difficulty caused by the limitation of the natural condition of the ocean is solved, and the utility model discloses a test simulation device all is convenient for operate and use, can observe clearly and record experimental process.

Description

Testing device for influence of natural gas hydrate decomposition on seabed slope

Technical Field

The utility model relates to an ocean disaster research technical field specifically is a natural gas hydrate decomposes test device to seabed slope influence.

Background

The ocean is a general term for the widest water body on the earth, the surface of the earth is divided into a large water area communicated with each other by each continent and is called as an ocean, the central part of the ocean is called as an ocean, and the edge parts of the ocean are called as seas, which are communicated with each other to form a uniform water body.

The research on the development and utilization of oceans and resources, the marine and global climate change, and the harmonious development of marine environment and ecology is the most feasible way for human beings to maintain the survival and development of the human beings, expand the living space and fully utilize the final treasure place with rich resources on the earth; the development and utilization of ocean resources and the construction of ocean engineering or the occurrence of ocean geological disasters which threaten the safety construction of the ocean engineering.

Natural Gas Hydrate (Natural Gas Hydrate/Gas Hydrate), organic compound, chemical formula CH₄·nH₂And O. Namely, the combustible ice is an ice-like crystalline substance which is distributed in deep sea sediments or permafrost in land areas and is formed by natural gas and water under high pressure and low temperature conditions.

They are also called "Combustible ice" (Combustible gas) or "solid gas" and "vapor ice" because they look like ice and burn on fire. In essence, a solid mass. Natural gas hydrates are widely distributed in nature in permanently frozen earth on continents, in sloping zones of islands, in elevations at the edges of active and passive continents, in polar continental stands, and in the deep water environment of the sea and some inland lakes.

The seabed natural gas hydrate decomposition can damage the seabed slope, but due to the difficulty of low-temperature and high-pressure environmental factors in deep sea and the restriction of natural ocean conditions, the seabed natural gas hydrate decomposition cannot be controlled artificially, so that the damage phenomenon of the seabed natural gas hydrate decomposition to the seabed slope stability is inconvenient to study.

Based on this, the utility model designs a natural gas hydrate decomposes test device to seabed slope influence to solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a natural gas hydrate decomposes test device to seabed slope influence to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

a test method for influence of natural gas hydrate decomposition on a seabed slope comprises the following steps:

s1, selecting a proper place, and sequentially placing a 100cm × 50cm × 70cm model box, a methane gas conveying device and a water vapor conversion device at corresponding positions;

s2, processing the model box, paving a layer of sandy soil with high air permeability of about 2cm at the bottom of the model box, buffering the impact capacity of airflow, paving a plurality of PEX perforated pipes on the top, wherein the perforated pipes are provided with holes with different sizes so as to enable water vapor and gas to be uniformly distributed and act on the bottom surface of a slope, the parts without holes at two ends penetrate through the left side and the right side of the model box, the extended parts are tightly and seamlessly combined with the model box, a test soil sample required by the test is paved into the slope with an inclination angle of 10 degrees, a simulated seawater solution added with Nacl solute is slowly poured into the model box, and the model box is kept stand for 5 days in a natural state;

s3, standing for 5 days, connecting the device for conveying methane gas on the left side with the left side extending end of the perforated pipe in the model box through the rubber pipe, pumping the methane gas, connecting the conveying pipe made of PEX material in the water vapor conversion device on the right side with the right side extending end of the perforated pipe in the model box, and performing the following steps according to the ratio of about 1: 165, inputting water and methane gas according to a volume ratio, and acting on the slope bottom of the model box;

s3, starting an experiment, preparing a camera to observe slope change, recording the damage condition of each time period of the slope in time, recording damage data, and further finding the relation of each variable in the critical state of slope damage;

s4, after the test is finished, water in the model box can be discharged through the water outlet hole in the lower part, and sediment, silt and the like in the model box are cleaned out.

Preferably, the soil sample tested in the S2 is used as a variable, the inclination angles of different slopes are changed, and slope failure is observed.

Preferably, the constituent substances of the soil sample tested in S2 are used as variables, the substances constituting the slope are changed, and the results generated by the internal structure of different types of slopes are observed.

The utility model provides a natural gas hydrate decomposes test device to seabed slope influence, including methane gas conveying device, the mold box, steam conversion equipment, be equipped with the rubber tube on the methane gas conveying device, be equipped with the flow graduation apparatus on the rubber tube, and one end evenly is provided with a plurality of branch pipes, the high water permeability sand bed has been laid to the bottom of mold box, the band hole pipe has evenly been laid on the high water permeability sand bed, the experimental soil sample of slope has been laid to the top of band hole pipe, the band hole pipe is provided with the hole of a plurality of variation in size on being located the pipeline section in the mold box, the mold box is stretched out at the both ends of band hole pipe, and the left end is connected with methane gas conveying device's rubber tube, the right-hand member is connected with the conveyer pipe, and.

Preferably, a water-proof baffle is fixed in the middle of an inner cavity of the water-vapor conversion device, a water tank is arranged on the lower portion of the inner cavity of the water-vapor conversion device, a piezoelectric ceramic piece is arranged at the bottom of the water tank, a waterproof fan, an adjustable voltage reduction module and a direct current motor speed regulator are arranged on the water-proof baffle, and a pressure adjusting switch button is arranged at the top of the water-vapor conversion device.

Preferably, the top of the water-steam conversion device is provided with a water inlet, and the bottom end of the water inlet penetrates through the waterproof baffle and is communicated with the water tank.

Preferably, a water volume scale pipe is arranged on the outer side wall of the water-steam conversion device corresponding to the water tank.

Preferably, the conveying pipe is made of PEX material, and the outer side wall of the conveying pipe is wrapped with polyethylene cotton to prevent the water in the steam state from being condensed and attached to the inner wall of the conveying pipe due to too low temperature.

Preferably, the bottom of the model box is provided with a water outlet, and a sealing cover is arranged at the water outlet.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the utility model converts the natural gas hydrate in the low-temperature and high-pressure environment in the deep sea into the practical operable controllable variable, and the analysis of the decomposed product of the natural gas hydrate acts on the seabed slope, thereby not only meeting the practical action damage condition, but also solving the difficulty limited by the ocean natural condition, and the utility model has convenient operation and use of the test simulation device, and can clearly observe and record the test process;

(2) the experimental model can not only observe the destructive action state of the seabed slope hydrate decomposition product, but also obtain other data by changing other variables of the model box, such as inclination angle, seawater solute content, different sediment types and the like, and the gas conveying device and the water-vapor conversion device can also be used for conveying and converting other factors;

(3) the test device can be processed and customized in a factory, the model is not very heavy, the installation is convenient, and the manpower and the test cost are saved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the bottom structure of the model box of the present invention;

fig. 3 is a schematic structural diagram of the water-steam conversion device of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1-methane gas conveying device, 2-flow graduator, 3-rubber tube, 4-high-permeability sand layer, 5-perforated tube, 6-test soil sample, 7-model box, 8-conveying tube, 9-water-vapor conversion device, 10-pressure adjusting switch button, 11-water-quantity graduated tube, 12-water filling port, 13-water outlet, 14-water-resisting baffle, 15-water tank, 16-piezoelectric ceramic plate, 17-waterproof fan, 18-adjustable voltage-reducing module and 19-direct current motor speed regulator.

Detailed Description

The technical solution in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention based on the embodiments of the present invention.

Referring to the drawings, the utility model provides a technical scheme:

the utility model provides a natural gas hydrate decomposes test device to seabed slope influence, including methane gas delivery device 1, mold box 7, steam conversion device 9, be equipped with rubber tube 3 on the methane gas delivery device 1, be equipped with flow graduation apparatus 2 on the rubber tube 3, and one end evenly is provided with a plurality of branch pipes, high water permeability sand bed 4 has been laid to mold box 7's bottom, mold box 7's bottom is equipped with delivery port 13, evenly laid perforated pipe 5 on the high water permeability sand bed 4, the experimental soil sample 6 of slope has been laid to perforated pipe 5's top, perforated pipe 5 is located and is provided with the hole of a plurality of variation in size on the pipeline section of mold box 7, mold box 7 is stretched out at perforated pipe 5's both ends, and the left end is connected with methane gas delivery device 1's rubber tube 3, the right-hand member is connected with conveyer pipe 8, and connect steam conversion device 9 through conveyer pipe 8.

A water-stop baffle 14 is fixed in the middle of an inner cavity of the water-vapor conversion device 9, a water tank 15 is arranged at the lower part of the inner cavity, a piezoelectric ceramic plate 16 is arranged at the bottom of the water tank 15, a waterproof fan 17, an adjustable voltage reduction module 18 and a direct current motor speed regulator 19 are arranged on the water-stop baffle 14, and a pressure adjusting switch button 10 is arranged at the top of the water-vapor conversion device 9; the top of the water-vapor conversion device 9 is provided with a water injection port 12, and the bottom end of the water injection port 12 penetrates through a water-stop baffle 14 and is communicated with a water tank 15; a water volume scale tube 11 is arranged on the outer side wall of the water vapor conversion device 9 corresponding to the water tank 15; the conveying pipe 8 is made of PEX material, and the outer side wall of the conveying pipe 8 is wrapped with polyethylene cotton to prevent the water in the steam state from being condensed and attached to the inner wall of the conveying pipe 8 due to too low temperature.

The basic parameters of the water-vapor conversion device 9 are as follows: the switch controls the fog-making quantity, the power supply is 220V/50HZ, the power of the converter is 600w, and the ventilation quantity is 150m 3/h.

In water vapour conversion equipment 9, fix waterproof fan 17 bonding in one side of inner chamber, water proof baffle 14 is arranged in the tip bonding of opposite side and waterproof fan 17, be connected direct current motor speed regulator 19 and adjustable voltage reduction module 18 and put on water proof baffle 14, pressure adjusting button 10 with direct current motor speed regulator 19 is fixed, line connection on the waterproof fan 17 is to direct current motor speed regulator, open a hole on waterproof fan 17's edge, the line of the piezoceramics piece 16 of water tank 15 bottom passes the hole, and weld on the adjustable voltage reduction module 18 line, with line connection switch, at last below water proof baffle 14 of outside of water vapour conversion equipment 9, set up water volume scale pipe 11 on the water tank 15.

When the water vapor conversion device 9 works, a driving voltage with the same resonant frequency as that of the piezoelectric ceramic piece 16 is applied to the piezoelectric ceramic piece 16 through a driving control circuit, the ceramic piece can generate oscillation energy, the oscillation energy can be concentrated in the propagation direction to form a water column, the front end of the water column is concentrated to form a large number of small tension waves, the water surface is split into a plurality of small areas by the tension waves, and independent micro-particles are formed and are emitted into a water vapor state. The variation of the quantity can be controlled by means of the pressure regulating button 10.

A test method for influence of natural gas hydrate decomposition on a seabed slope comprises the following steps:

s1, selecting a proper place, and sequentially placing a 100cm × 50cm × 70cm model box 7, a methane gas conveying device 1 and a water-vapor conversion device 9 at corresponding positions;

s2, processing a model box 7, paving a layer of sand with high air permeability of about 2cm at the bottom of the model box 7, buffering the impact capacity of airflow, paving a plurality of PEX perforated pipes 5 on the perforated pipes 5, arranging holes with different sizes on the perforated pipes 5 so as to enable water vapor and gas to be uniformly distributed and act on the bottom surface of a slope, enabling the parts without holes at two ends to penetrate through the left side and the right side of the model box 7, enabling the extending parts to be tightly and seamlessly combined with the model box 7, ensuring the tightness of the side wall at the bottom of the model box 7, paving a test soil sample 6 required by a test into the slope with an inclination angle of 10 degrees, slowly pouring a simulated seawater solution added with Nacl solute into the model box 7, and standing for 5 days in a natural state;

s3, standing for 5 days, connecting the device for conveying methane gas on the left side with the left extending end of the perforated pipe 5 in the model box 7 through the rubber pipe 3, pumping the methane gas, connecting the conveying pipe 8 made of PEX material in the water-steam conversion device 9 on the right side with the right extending end of the perforated pipe 5 in the model box 7, wherein the conveying pipe is 1m at normal temperature and normal pressure³Will yield 164.6 m³And 0.87m of methane³So that the ratio of about 1: 165 volume ratio water and methane gas are input and act on the slope bottom of the model box 7, and a water-steam conversion device 9 is provided with a 1m³The water capacity scale, left side methane input gas device can be through 2 observation control input volumes of scale above, all according to per hour 1: 165, carrying out the test;

s3, starting an experiment, preparing a camera to observe slope change, recording the damage condition of each time period of the slope in time, recording damage data, and further finding the relation of each variable in the critical state of slope damage;

s4, after the test is finished, water in the model box 7 can be discharged through a water outlet hole in the lower part, and sediment, silt and the like in the model box are cleaned.

The test can change different slope inclination angles as variables and observe the slope damage condition; the materials making up the ramp can also be varied to explore how the internal structure of the ramp will have.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the present invention disclosed above are intended to be illustrative only. The preferred embodiments are not exhaustive and do not limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (6)

1. The utility model provides a natural gas hydrate decomposes test device to seabed slope influence which characterized in that: comprises a methane gas conveying device (1), a model box (7) and a water-vapor conversion device (9), the methane gas conveying device (1) is provided with a rubber pipe (3), the rubber pipe (3) is provided with a flow rate dial gauge (2), and one end is uniformly provided with a plurality of branch pipes, the bottom of the model box (7) is paved with a high-water-permeability sand layer (4), the high-water-permeability sand layer (4) is uniformly paved with a perforated pipe (5), an inclined test soil sample (6) is paved above the perforated pipe (5), a pipe section of the perforated pipe (5) positioned in the model box (7) is provided with a plurality of holes with different sizes, two ends of the perforated pipe (5) extend out of the model box (7), and the left end is connected with the rubber tube (3) of the methane gas conveying device (1), and the right end is connected with a conveying pipe (8) and is connected with a water vapor conversion device (9) through the conveying pipe (8).

2. The apparatus for testing the effect of natural gas hydrate dissociation on a seafloor slope as claimed in claim 1, wherein: the water-proof type water vapor conversion device is characterized in that a water-proof baffle (14) is fixed in the middle of an inner cavity of the water vapor conversion device (9), a water tank (15) is arranged on the lower portion of the inner cavity, a piezoelectric ceramic piece (16) is arranged at the bottom of the water tank (15), a waterproof fan (17), an adjustable voltage reduction module (18) and a direct current motor speed regulator (19) are arranged on the water-proof baffle (14), and a pressure adjusting switch button (10) is arranged at the top of the water vapor conversion device (9).

3. The apparatus for testing the effect of natural gas hydrate dissociation on a seafloor slope as claimed in claim 2, wherein: the top of water vapour conversion equipment (9) is equipped with water filling port (12), and water proof baffle (14) are passed to the bottom of water filling port (12) to communicate with water tank (15).

4. The apparatus for testing the effect of natural gas hydrate dissociation on a seafloor slope as claimed in claim 2, wherein: and a water volume scale pipe (11) is arranged on the outer side wall of the water-vapor conversion device (9) corresponding to the position of the water tank (15).

5. The apparatus for testing the effect of natural gas hydrate dissociation on a seafloor slope as claimed in claim 2, wherein: the conveying pipe (8) is made of PEX material, and the outer side wall of the conveying pipe (8) is wrapped with polyethylene cotton.

6. The apparatus for testing the effect of natural gas hydrate dissociation on a seafloor slope as claimed in claim 1, wherein: a water outlet (13) is arranged at the bottom of the model box (7), and a sealing cover is arranged at the water outlet (13).

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