CN204389257U - A kind of generating apparatus of high saturation methane hydrate deposits thing sample - Google Patents

A kind of generating apparatus of high saturation methane hydrate deposits thing sample Download PDF

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Publication number
CN204389257U
CN204389257U CN201520103244.2U CN201520103244U CN204389257U CN 204389257 U CN204389257 U CN 204389257U CN 201520103244 U CN201520103244 U CN 201520103244U CN 204389257 U CN204389257 U CN 204389257U
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China
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gas
loop
valve
needle
methane
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CN201520103244.2U
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Chinese (zh)
Inventor
李清平
宋永臣
刘卫国
张炜
姚海元
赵佳飞
王世圣
朱一铭
庞维新
程兵
秦蕊
余敏
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Dalian University of Technology
China National Offshore Oil Corp CNOOC
CNOOC Research Institute Co Ltd
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Dalian University of Technology
China National Offshore Oil Corp CNOOC
CNOOC Research Institute Co Ltd
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Abstract

The utility model relates to a kind of generating apparatus of high saturation methane hydrate deposits thing sample, and it comprises mould, and mould inside has the cavity arranging piston, and piston base and cavity form the accommodation district for generating sediment sample; Be provided with thermopair in mould cavity, the temperature information detected is transferred to computer control system through data acquisition system (DAS) by thermopair; Mold exterior is disposed with clamper and heat interchanger, mould, piston, clamper and heat interchanger forming reactions still main body; Reactor bottom part body is provided with gas-holder loop, methane gas inflation loop, vacuumizes loop and pressure detection loop, methane gas inflation loop and gas-holder loop, vacuumize loop in parallel after, be communicated with bottom mould cavity through pressure detection loop; The vent port of piston is connected in parallel exhaust collection loop, gas exhaust piping and tail gas pressure control conduit by connecting line.The utility model can extensively be applied in gas hydrate Basic Physical Properties fields of measurement.

Description

A kind of generating apparatus of high saturation methane hydrate deposits thing sample
Technical field
The utility model relates to the sample preparation device in a kind of gas hydrate Basic Physical Properties fields of measurement, particularly about a kind of generating apparatus for the high saturation methane hydrate deposits thing sample in triaxial compression test.
Background technology
Gas hydrate are a kind of white group ice-like solid matters that natural gas molecule and hydrone are formed under the condition of low temperature high pressure.The component of rock gas is a lot, and principal ingredient is methane gas, and methane hydrate is a kind of highdensity energy mineral reserve, has very high extraction value, and in normal conditions, the methane hydrate of 1 volume can discharge the methane gas of 164 volumes in theory.So hydrate mineral reserve are a kind of highdensity energy mineral reserve, there is very high extraction value.When gas hydrate are exploited, continuous decomposition due to gas hydrate causes the continuous decrease of sediment mechanical strength, if do not intervened the geologic hazard (stratum dislocation causes earthquake) after likely causing the accident in recovery process (as loosening in derrick or well head subsides) or causing exploitation, so very important to the laboratory study of hydrate mechanical strength characteristics.
But the hydrate produced of classic method that laboratory adopts, saturation degree often can not higher than 30%, and the saturation degree of actual synthesis is even lower.Even if having employed various ways to carry out controlled condition generation methane hydrate, such as slowly pressurize, reduce initial temperature, improve the generating modes such as sample aperture porosity, the saturation degree generating methane hydrate is the highest also only reaches 25%.And the content in China's South Sea survey report, the saturation degree mxm. exploring the gas hydrate sample obtained at three sensing points in South China Sea marine site reaches 25.5%, 46%, 43% respectively, and this is the area that among the current gas hydrate storage area found in the world, methane hydrate saturation degree is the highest.So there is the saturation degree of the hydrate mineral reserve of extraction value, it is all often high saturation, compared with the saturation degree that the saturation degree that the method for existing product in laboratory hydrate obtains and occurring in nature are applicable to the hydrate mineral reserve that business is exploited, gap is very large, and corresponding mechanical strength characteristics will produce larger difference.
Summary of the invention
For the problems referred to above, the purpose of this utility model is to provide a kind of generating apparatus of high saturation methane hydrate deposits thing sample, it effectively can generate high saturation methane hydrate deposits thing sample, for follow-up further methane hydrate deposits thing mechanical property testing experiment is supplied raw materials, to test the difference of the mechanical characteristic of the methane hydrate of different saturation.
For achieving the above object, the utility model takes following technical scheme: a kind of generating apparatus of high saturation methane hydrate deposits thing sample, is characterized in that: it comprises mould, piston, thermopair, data acquisition system (DAS), computer control system, clamper, heat interchanger, gas-holder loop, methane gas inflation loop, vacuumizes loop, pressure detection loop, exhaust collection loop, gas exhaust piping and tail gas pressure control conduit; Described mould inside has a cavity, is provided with described piston in this cavity, and described piston base and described cavity form one for generating the accommodation district of sediment sample; Also be provided with described thermopair in described mould cavity, the temperature information detected is transferred to described computer control system through described data acquisition system (DAS) by described thermopair; Described mold exterior is disposed with described clamper and described heat interchanger, described mould, piston, clamper and heat interchanger forming reactions still main body; Described reactor bottom part body is provided with the described gas-holder loop, the methane gas that are communicated with it and inflates loop, vacuumizes loop and pressure detection loop, described methane gas inflation loop and described gas-holder loop, described in vacuumize loop in parallel after, be communicated with bottom described mould cavity through described pressure detection loop; Described piston is provided with vent port, and described vent port is connected in parallel described exhaust collection loop, gas exhaust piping and tail gas pressure control conduit by connecting line.
Described heat interchanger connects the first constant temperature waters for regulating temperature in reactor main body.
Described gas-holder loop comprises gas-holder, the second constant temperature waters, the first trimmer valve, the first gas meter and the first needle-valve, and described gas-holder is arranged in described second constant temperature waters; Described reservoir outlet end connects described first trimmer valve, the first gas meter and first needle-valve one end successively, the described first needle-valve other end and describedly vacuumize loop, methane gas inflates loop and pressure detection circuit communication.
Described methane gas inflation loop comprises methane gas cylinder, the second trimmer valve, the second needle-valve, gas booster, the second needle-valve and the first non-return valve; Described methane gas cylinder endpiece connects described second trimmer valve, the second needle-valve, gas booster, the second needle-valve and first non-return valve one end successively, the described first non-return valve other end and described gas-holder loop, vacuumizes loop and pressure detection circuit communication.
The described loop that vacuumizes comprises vacuum pump and the 3rd needle-valve, and described vacuum pump inflates loop and pressure detection circuit communication through described 3rd needle-valve and described gas-holder loop, methane gas.
Described pressure detection loop comprises pressure transducer and the 4th needle-valve, described gas-holder loop, vacuumize loop and methane gas inflation circuit end and be connected with described 4th needle-valve one end through described pressure transducer, the described 4th needle-valve other end is connected with described reactor main body by the road; Described pressure transducer is electrically connected with described computer control system through described data acquisition system (DAS).
Described exhaust collection loop comprises exhaust collection bottle, the 3rd trimmer valve, the 5th needle-valve, the second non-return valve and the second gas meter; Described exhaust collection bottle inlet end connects described 3rd trimmer valve, the 5th needle-valve, the second non-return valve and second gas meter one end successively, and the described second gas meter other end is in parallel with described gas exhaust piping and tail gas pressure control conduit.
Described gas exhaust piping is made up of the 6th needle-valve be arranged on pipeline.
The counterbalance valve that described tail gas pressure control pipe route is arranged on pipeline is formed.
The utility model is owing to taking above technical scheme, it has the following advantages: 1, because the gas participating in reaction when generating hydrate is methane gas, partial pressure that one of factor of the speed of carrying out and the final ratio that generates and saturation degree is methane gas instead of total gas pressure are reacted in impact, and (methane gas dividing potential drop is exactly methane molecule concentration, affect molecular diffusion rates, and then affect reaction rate and productive rate).In order to improve methane gas dividing potential drop, the utility model adopts following two kinds of measures, one is improve methane gas dividing potential drop by the mode of raising total gas pressure, and specific practice uses gas booster to increase the partial pressure of methane gas; Two is improve methane gas dividing potential drop by the mode of the ratio of raising methane gas in insufflation gas, specific practice was exhausted reactor main body methane gas and vacuumizes before being filled with methane gas, and use more highly purified methane gas to generate experiment to do methane hydrate when testing.2, because another reactant participating in reaction is ice, but not pure water when icing because the ion concentration in liquid changes and then cause the complicated of icing situation, the utility model is in order to get rid of other influences factor as much as possible to study the impact of single factors on hydrate characteristic, before experiment starting, using distilled water cleaning reaction still inwall and sample forming die, adopting when testing deionized water to generate methane hydrate.3, the utility model is in methane hydrate generative process, the methane hydrate that the interface contacted with ice Particle Phase to prevent methane gas generates forms barrier and hinders methane gas to contact with the further of ice particle, adopts the method for control temperature to address this problem.Promote reactor main body environment temperature, make environment temperature higher than the fusing point 273.15K of ice, but lower than the decomposition temperature 293K of methane hydrate, impel part ice particle to be progressively melted into aqueous water, the aqueous water of methane gas and partial melting is reacted.Because aqueous water has mobility, the gap of the barrier of gas hydrate synthesis can be produced, so the method for this heating reactant can impel water to change into methane hydrate completely, and the method can control the growth pattern of crystal grain, the methane hydrate finally obtained or granular solids accumulation thing.4, the utility model adopts the reactor main body be made up of piston, mould, clamper and heat interchanger to produce high saturation methane hydrate deposits thing sample, directly can obtain the sample needed for Experiments of Machanics, after the sediment sample containing ice of the obtained volume required size of Experiments of Machanics, carry out methane hydrate generative process immediately, the final high saturation that formed is of a size of methane hydrate deposits thing sample.The utility model can extensively be applied in gas hydrate Basic Physical Properties fields of measurement.
Accompanying drawing explanation
Fig. 1 is the one-piece construction schematic diagram of the utility model experimental provision.
Embodiment
Below in conjunction with drawings and Examples, the utility model is described in detail.
As shown in Figure 1, the utility model provides a kind of generating apparatus of high saturation methane hydrate deposits thing sample, and it comprises mould 1, piston 2, thermopair 3, data acquisition system (DAS) 4, computer control system 5, clamper 6, heat interchanger 7, gas-holder loop, methane gas inflation loop, vacuumizes loop, pressure detection loop, exhaust collection loop, gas exhaust piping and tail gas pressure control conduit.
Mould 1 inside has a cavity, is provided with piston 2 in this cavity, forms one for generating the accommodation district of sediment Sample A bottom piston 2 with cavity; In mould 1 cavity, be also provided with thermopair 3, the temperature information detected is transferred to computer control system 5 through data acquisition system (DAS) 4 by thermopair 3, realizes the monitoring to temperature.Mould 1 outer setting has clamper 6, is installed on testing table by clamper 6 by mould 1; And have heat interchanger 7 in clamper 6 outer setting, by mould 1, piston 2, clamper 6 and heat interchanger 7 forming reactions still main body.Reactor bottom part body is provided with the gas-holder loop, the methane gas that are communicated with it and inflates loop, vacuumizes loop and pressure detection loop, methane gas inflation loop and gas-holder loop, vacuumize after loop is connected in parallel, be communicated with mould 1 cavity bottom through pressure detection loop.Be positioned at reactor body top, piston 2 is provided with vent port, vent port is connected in parallel exhaust collection loop, gas exhaust piping and tail gas pressure control conduit by connecting line.
In above-described embodiment, clamper 6 adopts the cylindrical structure be made up of high density polyethylene.Heat interchanger 7 connects the first constant temperature waters 8, is regulated the temperature in reactor main body by the first constant temperature waters 8.
In the various embodiments described above, gas-holder loop comprises gas-holder 9, second constant temperature waters 10, first trimmer valve 11, first gas meter 12 and the first needle-valve 13, gas-holder 9 is arranged in the second constant temperature waters 10, is regulated the temperature in gas-holder 9 by the second constant temperature waters 10.Gas-holder 9 endpiece connects first trimmer valve 11, first gas meter 12 and first needle-valve 13 one end successively, first needle-valve 13 other end with vacuumize loop, methane gas inflates loop and pressure detection circuit communication.Wherein, the ethanol water that massfraction is 95% is all filled in the first constant temperature waters 10, constant temperature waters 8, second.
In the various embodiments described above, methane gas inflation loop comprises methane gas cylinder 14, second trimmer valve 15, second needle-valve 16, gas booster 17, second needle-valve 18 and the first non-return valve 19.Methane gas cylinder 14 endpiece connects the second trimmer valve 15, second needle-valve 16, gas booster 17, second needle-valve 18 and first non-return valve 19 one end successively, first non-return valve 19 other end and gas-holder loop, vacuumizes loop and pressure detection circuit communication.Wherein, the maximum pressure capacity of gas booster 17 is 200MPa, and being used for increases methane gas pressure.
In the various embodiments described above, vacuumize loop and comprise vacuum pump 20 and the 3rd needle-valve 21, vacuum pump 20 inflates loop and pressure detection circuit communication through the 3rd needle-valve 21 with gas-holder loop, methane gas.
In the various embodiments described above, pressure detection loop comprises pressure transducer 22 and the 4th needle-valve 23, gas-holder loop, vacuumize loop and methane gas inflation circuit end and be connected with the 4th needle-valve 23 one end through pressure transducer 22, the 4th needle-valve 23 other end is connected with reactor main body by the road.Pressure transducer 22 is electrically connected with computer control system 5 through data acquisition system (DAS) 4, data acquisition system (DAS) 4 will collect pressure and temperature information transmission in computer control system 5, be realized controlling the temperature and pressure of the utility model device by computer control system 5.During use, when the 4th needle-valve 23 is closed and (namely the first needle-valve 13 is opened) is opened in gas-holder loop, pressure transducer 22 is for detecting the pressure in gas-holder 9; When the 4th needle-valve 23 is opened and (namely the first needle-valve 13 is closed) is closed in gas-holder loop, pressure transducer 22 is for the pressure in detection reaction still main body.Methane gas pressure in pipeline can also be monitored by pressure transducer 22, computer control system 5.Measurement pressure in the present embodiment is absolute pressure, and precision is ± 0.02%.
In the various embodiments described above, exhaust collection loop is for collecting the methane gas of non-total overall reaction in reactor main body, it comprises exhaust collection bottle 24, the 3rd trimmer valve 25, the 5th needle-valve 26, second non-return valve 27 and the second gas meter 28, exhaust collection bottle 24 inlet end connects the 3rd trimmer valve 25, the 5th needle-valve 26, second non-return valve 27 and second gas meter 28 one end successively, and second gas meter 28 other end is in parallel with gas exhaust piping and tail gas pressure control conduit.
In the various embodiments described above, gas exhaust piping is made up of the 6th needle-valve 29 be arranged on pipeline, when the 6th needle-valve 29 is opened, and can by gas all in gas exhaust piping outside whole discharge chamber.
In the various embodiments described above, the counterbalance valve 30 that tail gas pressure control pipe route is arranged on pipeline is formed, and is controlled the pressure of methane gas in reactor main body by counterbalance valve 30.
In the various embodiments described above, store gas tank 9 and be made up of stainless steel, its inner total measurement (volume) is 315cm 3, maximum pressure-bearing is 140MPa.
In the various embodiments described above, mould 1 adopts corrosion-resistant stainless steel to make, and it is of a size of sediment Sample A standard compression ratio is 1:1.6, and load mode can select constant speed rate to load the modes such as constant-pressure loading.Working temperature is-15 DEG C to+40 DEG C; Maximum load pressure is 50MPa, and precision is 0.5MPa; Temperature test scope is-30 DEG C to+40 DEG C, and precision is 0.3 DEG C; Pressure test scope is 0MPa to 20MPa, and precision is 0.2MPa.
As shown in Figure 1, based on the generating apparatus of above-mentioned high saturation methane hydrate deposits thing sample, the utility model also provides a kind of generation method of high saturation methane hydrate deposits thing sample, and it comprises the following steps:
1) be prepared in advance for subsequent use with deionized water freezing manufacture ice cube: deionized water needs to boil under methane gas environment and rises once, thoroughly to remove the foreign gas be dissolved in water; Then in low-pressure methane compression ring border, ice cube is frozen into.
2) use distilled water cleaning reaction still main body in advance, the impurity effect experimental result preventing previous run from staying, and mould 1 is used distilled water clean dry.
3) greenhouse cooling in the first constant temperature waters 10, constant temperature waters 8, second is controlled to 250K: this temperature-fall period needs a period of time, about 1 hours, needs to carry out in advance.
4) after cold storehouse temperature is lower than zero degrees celsius (in order to anti-stagnant ice particle melts), ice cube is pulverized after milling and get with screen cloth sieve the ice particle that grain diameter is 180 ~ 250 microns.Be mix ice particle and mean grain size after the sand grain of 0.6mm weighs according to precalculated quality, and put into clean mould 1, then mould 1 to be put in clamper 6 and to insert thermopair 3, being inserted in heat interchanger 7 in clamper 6 outside afterwards, finally sealed reactor main body.
5) by piston 2 by mixed uniformly ice particle and sand grain compression forming to standard volume be the sample containing ice with certain factor of porosity can be obtained.
6) by methane gas cylinder 14 respectively in reactor main body and store in gas tank 9 and pass into methane gas and carry out scavenging, the air stored in gas tank 9 and reactor main body is discharged, then by vacuum pump 20, reactor main body and storage gas tank 9 are vacuumized, to reduce the impact of the gases such as air on experiment as much as possible.
7) by gas-holder loop, methane gas inflation loop, methane gas is passed in storage gas tank 9, storing gas tank 9 is placed in the second constant temperature waters 10, and with gas booster 17, the pressure stored in gas tank 9 is increased to 35MPa, now the high pressure methane gas stored in gas tank 9 causes temperature to raise due to compression, the second constant temperature waters 10 is needed to be cooled to 250K, through multi-time inflating compression cooling, until the methane gas temperature stored in gas tank 9 reaches 250K, pressure reaches 35Mpa.Then the 4th needle-valve 23 carefully opened reactor main body and store between gas tank 9, pours in reactor main body by the methane gas stored in gas tank 9; In order to prevent from inflating, too fast methane gas temperature is too high to be melted completely by tiny ice particle, and methane gas must slowly pour in reactor until reactor pressure reaches 25MPa.
8), after the temperature, pressure parameter stability in question response still main body, the temperature in the first constant temperature waters 8 is regulated, and then by the temperature in heat interchanger 7 slowly lifting reactor main body to 273K.When temperature is lower than 273K, methane gas pressure can be linear along with the increase of temperature increase, this is because equation of gas state PV=nRT (P is the pressure of ideal gas, V is the volume of ideal gas, n is the amount of gaseous matter, T is the thermodynamic temperature of ideal gas, and R is ideal gas constant) the normal phenomenon that causes of reason, illustrate that this stage hydrate does not generate or formation speed almost can be ignored very slowly; When temperature rises to 273K, keep a period of time, now ice heat absorption is melted into water and starts to generate hydrate; Continue to heat up, when temperature rises to higher than 273K, because the quick generation of methane hydrate consumes methane gas, thus now cause the ascending velocity of methane air pressure slack-off relative to the ascending velocity of temperature.
9) after the temperature in reactor main body is increased beyond 273K, continue heating and make the specimen temperature in reactor main body and methane gas temperature remain between 288 ~ 290K, promote the further generation of methane hydrate, and keep 12 ~ 15 hours.The time dependent data of temperature, pressure parameter of whole generative process transfer to computer control system 5 by data acquisition system (DAS) 4, generate temperature, pressure curve to monitor in computer control system 5.In the process, when temperature-resistant, methane gas gaseous tension decline, illustrated that methane hydrate generates in a large number and consumes methane gas.
10) after 12 ~ 15 hours, when pressure drop in reactor main body is to 3.6MPa close to theory calculate, namely mark reaction is substantially complete, is calculated the methane gas scale of construction of consumption, thus calculate the saturation degree of whole sediment sample by PV=nRT.At this moment regulate the temperature in the first constant temperature waters 8, start to reduce temperature to initial temperature 250K to reactor main body by heat interchanger 7.
11) in reactor main body temperature-fall period, judge that temperature, pressure curve is near 273K time by computer control system 5, whether be straight-line pass: if temperature, pressure curve is straight line, then the sign that water congeals into ice is described, all ice particle complete reactions generate methane hydrate, then continuing to reduce temperature makes temperature in reactor main body finally be 250K and stablize a period of time, open tail gas acquisition equipment 15, open the 6th needle-valve 29, counterbalance valve 30 reduces unreacted methane gas gaseous tension, finally open reactor main body, take out sediment sample, so that the mechanics compression experiment carrying out next step observes its mechanical characteristic, if instead temperature, pressure curve is not straight line but a broken line exists jump (having occurred the phenomenon causing gaseous tension to increase suddenly because of water freezing volumetric expansion when falling at temperature), then illustrate have that water congeals into ice, now react still incomplete, needs reheat, repeat above-mentioned steps 7) to 10) and heating process with promotes reaction generation.
The various embodiments described above are only for illustration of the utility model; the structure of each parts, size, setting position and shape all can change to some extent; on the basis of technical solutions of the utility model; all improvement of carrying out individual part according to the utility model principle and equivalents, all should not get rid of outside protection domain of the present utility model.

Claims (10)

1. a generating apparatus for high saturation methane hydrate deposits thing sample, is characterized in that: it comprises mould, piston, thermopair, data acquisition system (DAS), computer control system, clamper, heat interchanger, gas-holder loop, methane gas inflation loop, vacuumizes loop, pressure detection loop, exhaust collection loop, gas exhaust piping and tail gas pressure control conduit;
Described mould inside has a cavity, is provided with described piston in this cavity, and described piston base and described cavity form one for generating the accommodation district of sediment sample; Also be provided with described thermopair in described mould cavity, the temperature information detected is transferred to described computer control system through described data acquisition system (DAS) by described thermopair; Described mold exterior is disposed with described clamper and described heat interchanger, described mould, piston, clamper and heat interchanger forming reactions still main body; Described reactor bottom part body is provided with the described gas-holder loop, the methane gas that are communicated with it and inflates loop, vacuumizes loop and pressure detection loop, described methane gas inflation loop and described gas-holder loop, described in vacuumize loop in parallel after, be communicated with bottom described mould cavity through described pressure detection loop; Described piston is provided with vent port, and described vent port is connected in parallel described exhaust collection loop, gas exhaust piping and tail gas pressure control conduit by connecting line.
2. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 1, is characterized in that: described heat interchanger connects the first constant temperature waters for regulating temperature in reactor main body.
3. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 1 or 2, it is characterized in that: described gas-holder loop comprises gas-holder, the second constant temperature waters, the first trimmer valve, the first gas meter and the first needle-valve, described gas-holder is arranged in described second constant temperature waters; Described reservoir outlet end connects described first trimmer valve, the first gas meter and first needle-valve one end successively, the described first needle-valve other end and describedly vacuumize loop, methane gas inflates loop and pressure detection circuit communication.
4. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 1 or 2, is characterized in that: described methane gas inflation loop comprises methane gas cylinder, the second trimmer valve, the second needle-valve, gas booster, the second needle-valve and the first non-return valve; Described methane gas cylinder endpiece connects described second trimmer valve, the second needle-valve, gas booster, the second needle-valve and first non-return valve one end successively, the described first non-return valve other end and described gas-holder loop, vacuumizes loop and pressure detection circuit communication.
5. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 1 or 2, it is characterized in that: described in vacuumize loop and comprise vacuum pump and the 3rd needle-valve, described vacuum pump inflates loop and pressure detection circuit communication through described 3rd needle-valve and described gas-holder loop, methane gas.
6. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 1, it is characterized in that: described pressure detection loop comprises pressure transducer and the 4th needle-valve, described gas-holder loop, vacuumize loop and methane gas inflation circuit end and be connected with described 4th needle-valve one end through described pressure transducer, the described 4th needle-valve other end is connected with described reactor main body by the road; Described pressure transducer is electrically connected with described computer control system through described data acquisition system (DAS).
7. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 1 or 2, is characterized in that: described exhaust collection loop comprises exhaust collection bottle, the 3rd trimmer valve, the 5th needle-valve, the second non-return valve and the second gas meter; Described exhaust collection bottle inlet end connects described 3rd trimmer valve, the 5th needle-valve, the second non-return valve and second gas meter one end successively, and the described second gas meter other end is in parallel with described gas exhaust piping and tail gas pressure control conduit.
8. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as described in claim 1,2 or 6, is characterized in that: described gas exhaust piping is made up of the 6th needle-valve be arranged on pipeline.
9. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as described in claim 1,2 or 6, is characterized in that: the counterbalance valve that described tail gas pressure control pipe route is arranged on pipeline is formed.
10. the generating apparatus of a kind of high saturation methane hydrate deposits thing sample as claimed in claim 3, is characterized in that: the counterbalance valve that described tail gas pressure control pipe route is arranged on pipeline is formed.
CN201520103244.2U 2015-02-12 2015-02-12 A kind of generating apparatus of high saturation methane hydrate deposits thing sample Withdrawn - After Issue CN204389257U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104634635A (en) * 2015-02-12 2015-05-20 中国海洋石油总公司 Device and method for generating high-saturation methane hydrate sediment sample
CN107313754A (en) * 2017-07-28 2017-11-03 中国地质调查局油气资源调查中心 A kind of gas hydrates develop the injected system of analogue experiment installation

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104634635A (en) * 2015-02-12 2015-05-20 中国海洋石油总公司 Device and method for generating high-saturation methane hydrate sediment sample
CN107313754A (en) * 2017-07-28 2017-11-03 中国地质调查局油气资源调查中心 A kind of gas hydrates develop the injected system of analogue experiment installation

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