CN208672488U - A kind of pressure chamber structure and permeability test macro - Google Patents

A kind of pressure chamber structure and permeability test macro Download PDF

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Publication number
CN208672488U
CN208672488U CN201821485511.7U CN201821485511U CN208672488U CN 208672488 U CN208672488 U CN 208672488U CN 201821485511 U CN201821485511 U CN 201821485511U CN 208672488 U CN208672488 U CN 208672488U
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pressure
cylinder
chamber
pressure chamber
piston
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张路青
李晓
周剑
李建彬
杨多兴
王颂
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Hunan Tuoxin Testing Equipment Co ltd
Institute of Geology and Geophysics of CAS
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Hunan Tuoxin Testing Equipment Co ltd
Institute of Geology and Geophysics of CAS
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Abstract

The utility model provides a kind of pressure chamber structure and permeability test macro, is related to experiment survey meter device technical field.The pressure chamber structure includes axis pressure chamber, pressure indoor and piston rod;The axis pressure chamber includes cylinder block and cylinder cover;The pressure indoor includes pressure indoor upper cover, cylinder and pedestal;The piston rod includes the body of rod, first piston and second piston;Pressure communication hole and counter balance pocket are provided between the body of rod and cylinder, form confining pressure self-compensating structure, it ensure that acting on second piston upper ring surface and the confining pressure of body of rod lower end surface can cancel out each other, to not interfere the load of axis pressure, make it possible to realize efficient axis pressure load.The utility model solve can not be offset when the pressure load of axis present in existing permeability measuring technology confining pressure bring pressure disturbances, condition of high voltage difficult to realize biaxial loadings, do not account for the technical issues of temperature effect, structure is complicated aspect.

Description

A kind of pressure chamber structure and permeability test macro
Technical field
The utility model relates to experiment survey meter device technical fields, survey more particularly, to a kind of pressure chamber structure and permeability Test system.
Background technique
As the basic physical parameters of rock, permeability is in evaluation oil gas field yield, underground natural gas storage tank and nuclear waste disposal It is particularly significant when the fracturing effect of hot dry rock in the airtightness in library and enhanced geothermal system.Especially shale oil in recent years The progress of the exploitation and reservoir scale hot dry rock crushing test energetically of the unconventional oil and gas such as gas, tight sand oil gas, urgently needs Precise measurement is carried out to the permeability of the Oil in Super-low Permeability rock such as shale, tight sand, granite.
The permeability test of Oil in Super-low Permeability rock is different from conventional hypertonic rock.Since Oil in Super-low Permeability rock is finer and close, seep Flow velocity degree is far below hypertonic rock, therefore Oil in Super-low Permeability test is long with the period, technical difficulty is big, equipment performance requires high spy Point.Currently, for permeability survey method there are mainly two types of: directly utilize Darcy's law steady state method and indirect utilization darcy The cold store enclosure of law.Steady state method is suitble to measure the porous media of high permeability, and cold store enclosure is more suitable and measures Oil in Super-low Permeability Rock.Cold store enclosure is divided into pulse attenuation method and rectilinear oscillation method again: pulse attenuation method is to apply one in the upstream end of sample Transient pulse pressure determines the permeability of sample then according to the changing rule of upstream and downstream end gas pressure;Rectilinear oscillation Method is to apply a cycle waveform pressure in the upstream of sample, calculates permeability according to the oscillatory response in downstream.In practical application In, the realization of rectilinear oscillation method needs more complicated experimental facilities, and cost is larger, and too sensitive to temperature change, under the influence of Swim pressure response.Therefore, pulse attenuation method is more applied in Oil in Super-low Permeability test.
Temperature and pressure influences rock permeability very big.Different from U.S. shale gas 1500m with shallow reservoir, China is non- Conventional gas and oil is mostly 3500m with deep reservoir, and the rock in stratum depths subjects higher pressure and temperature.In the prior art In, unreasonable due to the design of Oil in Super-low Permeability pressure chamber structure, Oil in Super-low Permeability test equipment is suitable for 50MPa, shallow within 40 DEG C more Layer Temperature-pressure Conditions are far from satisfying 3500m and are simulated with deep Temperature-pressure Conditions.In addition, deep reservoir is in two-way anisobaric shape State, current technology majority only account for the test of the permeability under hydrostatic confining pressure, cannot represent true reservoir pressure state.
There is certain defects in the instrument of measurement Oil in Super-low Permeability rock permeability at present.For example, Chinese Patent Application No. 201610946045.7 disclosing a kind of lower Oil in Super-low Permeability rock permeability measuring device of triaxial stress effect.The pressure chamber of the device Unreasonable structural design does not have pressure autocompensation structure, so that device can not offset confining pressure bring pressure when adding axis to press and do It disturbs, is difficult to realize condition of high voltage load, while the device does not account for temperature effect yet.Therefore, which it is true to be not suitable for simulation On the spot under the conditions of layer rock permeability measurement.For another example Chinese Patent Application No. 201410109565.3 discloses a kind of use In the high airtightness pressure vessel of rock fracture seepage flow microseism test.The device will permeate to simulate two-way anisobaric state Test device depends in Rock Under Uniaxial Compression press machine, applies axis pressure by uniaxial tension testing machine, and this considerably increases tests to be The complexity of system, test effect are to be improved.
Based on this, the utility model provides a kind of pressure chamber structure and permeability test macro, to solve above-mentioned technology Problem.
Utility model content
The purpose of this utility model is to provide a kind of pressure chamber structures, to solve to exist in existing permeability measuring technology Axis press can not be offset when load confining pressure bring pressure disturbances, condition of high voltage difficult to realize biaxial loadings, do not account for temperature Spend effect and structure is complicated aspect the technical issues of.
The purpose of this utility model, which also resides in, provides a kind of permeability test macro, and the permeability test macro includes upper Pressure chamber structure being stated, confining pressure bring pressure disturbances, can not be offset very much when for solving axis existing in the prior art pressure load Hardly possible realize condition of high voltage biaxial loadings, do not account for temperature effect and structure is complicated aspect the technical issues of.
Based on above-mentioned first purpose, the utility model provides a kind of pressure chamber structure, including axis pressure chamber, pressure indoor and work Stopper rod;
The axis pressure chamber includes cylinder block and cylinder cover;The pressure indoor includes pressure indoor upper cover, cylinder and pedestal; The piston rod includes the body of rod, first piston and second piston;
The cylinder block includes first chamber;The cylinder includes second chamber, third chamber and pressure communication hole, institute State second chamber and the third chamber by segregated portion every;The body of rod sequentially passes through the oil cylinder by the first chamber Cylinder body, the pressure indoor upper cover, the second chamber, the lattice are until the third chamber;The first piston setting In the first chamber;The second piston is arranged in the second chamber;
The cylinder cover and the first chamber lid close, and axis pressure is formed between the first piston and the cylinder cover Chamber;The pressure indoor upper cover and the second chamber lid close, and balance is formed between the pressure indoor upper cover and the second piston Chamber;The pedestal and the third chamber cover are closed, and form confining pressure chamber after the pedestal, the cylinder and body of rod cooperation;Institute It states counter balance pocket and is connected to the confining pressure chamber by pressure communication hole;
The cylinder block is fixed in the pressure indoor on lid.
Optionally, above-mentioned pressure chamber structure further includes thermal insulation board;
The thermal insulation board is arranged between the cylinder block and the pressure indoor upper cover.
Optionally, above-mentioned pressure chamber structure, between the cylinder block and the cylinder cover, the cylinder block and institute It states between first piston, sealed by first seal between the cylinder block and the body of rod.
Optionally, above-mentioned pressure chamber structure, between the pressure indoor upper cover and the body of rod, the pressure indoor upper cover and institute State between cylinder, between the second piston and the cylinder, between the body of rod and the lattice, the cylinder with it is described It is sealed by second seal between pedestal.
Optionally, above-mentioned pressure chamber structure, the first seal are ordinary seals;The second seal is abnormity Sealing element.
Optionally, above-mentioned pressure chamber structure further includes heating coil;
The heating coil is set on the outer surface of the cylinder.
Optionally, above-mentioned pressure chamber structure further includes test suite;
The test suite includes test specimen seaming chuck, test specimen push-down head and Sample sleeve;
The test specimen seaming chuck, the test specimen push-down head one end respectively with two end in contact of test specimen, contact site and institute Test specimen is stated to be arranged in the Sample sleeve;The other end of the test specimen seaming chuck is contacted with the body of rod;The test specimen push-down head The other end connect with the pedestal.
Optionally, above-mentioned pressure chamber structure is provided with seepage flow import and seepage exit on the pedestal;
Inlet ductwork is provided between the seepage flow import and the test specimen seaming chuck;
Export pipeline is provided between the seepage exit and the test specimen push-down head.
Based on above-mentioned second purpose, the utility model provides a kind of permeability test macro, permeability test system System includes pipeline gas circuit unit, temperature control unit, acquisition control unit and the pressure chamber structure;
The pipeline gas circuit unit is connect with the pressure chamber structure;The acquisition control unit and the pipeline gas circuit list Member connection;
The pipeline gas circuit unit is used to test the connection and separation of required fluid;The temperature control unit is for controlling The temperature of the pipeline gas circuit unit and the pressure chamber structure is constant;The acquisition control unit is described for acquiring and controlling Pressure information, temperature information and the flow information of pipeline gas circuit unit, the temperature control unit and the pressure chamber structure.
Optionally, above-mentioned permeability test macro, the pipeline gas circuit unit include upstream pressure sensor, downstream pressure Sensor, differential pressure pickup and temperature sensor.
The pressure chamber structure provided by the utility model, including axis pressure chamber, pressure indoor and piston rod;The axis pressure chamber packet Include cylinder block and cylinder cover;The pressure indoor includes pressure indoor upper cover, cylinder and pedestal;The piston rod include the body of rod, First piston and second piston;The cylinder block includes first chamber;The cylinder includes second chamber, third chamber and pressure Power intercommunicating pore, the second chamber and the third chamber by segregated portion every;The body of rod by the first chamber successively Across the cylinder block, the pressure indoor upper cover, the second chamber, the lattice until the third chamber;It is described First piston is arranged in the first chamber;The second piston is arranged in the second chamber;The cylinder cover with The first chamber lid closes, and forms axis between the first piston and the cylinder cover and presses chamber;The pressure indoor upper cover and institute The conjunction of second chamber lid is stated, forms counter balance pocket between the pressure indoor upper cover and the second piston;The pedestal and the third Chamber cover is closed, and forms confining pressure chamber after the pedestal, the cylinder and body of rod cooperation;The counter balance pocket and the confining pressure chamber are logical The connection of excess pressure intercommunicating pore;The cylinder block is fixed in the pressure indoor on lid.Pressure chamber's knot provided by the utility model Structure is provided with pressure communication hole and counter balance pocket, forms confining pressure self-compensating structure between the body of rod and cylinder, ensure that and act on the Two piston upper ring surfaces and the confining pressure of body of rod lower end surface can cancel out each other, to not interfere the load of axis pressure, make it possible to realize height The axis of effect presses load.
The permeability test macro provided by the utility model includes pipeline gas circuit unit, temperature control unit, acquisition Control unit and the pressure chamber structure;The pipeline gas circuit unit is connect with the pressure chamber structure;The acquisition control Unit processed is connect with the pipeline gas circuit unit.The pipeline gas circuit unit is used to test the connection and separation of required fluid;Institute Temperature control unit is stated for controlling the pipeline gas circuit unit and the temperature of the pressure chamber structure is constant;The acquisition control Unit is used to acquire and control the pressure letter of the pipeline gas circuit unit, the temperature control unit and the pressure chamber structure Breath, temperature information and flow information.Permeability test macro provided by the utility model has used above-mentioned pressure chamber structure, tool There are all advantages of above-mentioned pressure chamber structure, and be applicable to two kinds of permeability test methods of steady state method and pulse attenuation method, Permeability test can either be carried out to complete Oil in Super-low Permeability rock, additionally it is possible to containing crannied Oil in Super-low Permeability rock or other are hypertonic Saturating rock carries out permeability test.
Based on this, compared with existing permeability measuring technology, the utility model can not only realize that efficient axis pressure adds The biaxial loadings with condition of high voltage are carried, and also contemplate temperature effect.
Detailed description of the invention
It, below will be right in order to illustrate more clearly of specific embodiment of the present invention or technical solution in the prior art Specific embodiment or attached drawing needed to be used in the description of the prior art are briefly described, it should be apparent that, it is described below In attached drawing be that some embodiments of the utility model are not paying creativeness for those of ordinary skill in the art Under the premise of labour, it is also possible to obtain other drawings based on these drawings.
Fig. 1 is the first structural schematic diagram of pressure chamber structure provided by the embodiment of the utility model;
Fig. 2 is the enlarged drawing in Fig. 1 at A;
Fig. 3 is the structural schematic diagram of piston rod in pressure chamber structure provided by the embodiment of the utility model;
Fig. 4 is second of structural schematic diagram of pressure chamber structure provided by the embodiment of the utility model;
Fig. 5 is the structural schematic diagram of permeability test macro provided by the embodiment of the utility model.
Icon: 1- cylinder cover;2- oil cylinder B mouth;3- cylinder block;A mouthfuls of 4- oil cylinder;5- upper cover attachment screw;6- confining pressure Room upper cover;7- counter balance pocket;8- Special-shaped seal components;81- guide sleeve;9- heating coil;10- Sample sleeve;11- inlet ductwork;12- cylinder; 13- pedestal;14- seepage flow import;15- seepage exit;16- confining pressure inlet and outlet;17- export pipeline;The pressure chamber 18- attachment screw; 19- test specimen push-down head;20- test specimen;21- test specimen seaming chuck;22- pressure communication hole;23- ordinary seals;24- piston rod; The 241- body of rod;242- first piston;243- second piston;25- oil cylinder attachment screw;26- cylinder cap attachment screw;27- thermal insulation board; 28- vacuum pump;29- flowmeter;30- three-position three-way valve A;31- three-position three-way valve B;The first valve of 32-;The second valve of 33-;34- Third valve;The 4th valve of 35-;The 5th valve of 36-;The first gas injection of 37- pump;The second gas injection of 38- pump;The upstream 39a- air accumulator; 39b- downstream gas tank;40- differential pressure pickup;41a- upstream pressure sensor;41b- downstream pressure sensor;42- temperature passes Sensor;43- axis press pump;44- confining pressure pump;45- acquisition controller;46- insulating box.
Specific embodiment
The technical solution of the utility model is clearly and completely described below in conjunction with attached drawing, it is clear that described Embodiment is the utility model a part of the embodiment, instead of all the embodiments.Based on the embodiments of the present invention, originally Field those of ordinary skill every other embodiment obtained without making creative work belongs to practical Novel protected range.
It is in the description of the present invention, it should be noted that term " center ", "upper", "lower", "left", "right", " perpendicular Directly ", the orientation or positional relationship of the instructions such as "horizontal", "inner", "outside" is to be based on the orientation or positional relationship shown in the drawings, and is only For ease of description the utility model and simplify description, rather than the device or element of indication or suggestion meaning must have it is specific Orientation, be constructed and operated in a specific orientation, therefore should not be understood as limiting the present invention.In addition, term " the One ", " second ", " third " are used for descriptive purposes only and cannot be understood as indicating or suggesting relative importance.
In the description of the present invention, it should be noted that unless otherwise clearly defined and limited, term " is pacified Dress ", " connected ", " connection " shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integrally Connection;It can be mechanical connection, be also possible to be electrically connected;Can be directly connected, can also indirectly connected through an intermediary, It can be the connection inside two elements.For the ordinary skill in the art, above-mentioned art can be understood with concrete condition The concrete meaning of language in the present invention.
Embodiment one
Fig. 1 is the first structural schematic diagram of pressure chamber structure provided by the embodiment of the utility model;Fig. 2 is in Fig. 1 at A Enlarged drawing;Fig. 3 is the structural schematic diagram of piston rod in pressure chamber structure provided by the embodiment of the utility model.
As shown in Figure 1, provide a kind of pressure chamber structure in the present embodiment, the pressure chamber structure include axis pressure chamber, Pressure indoor and piston rod 24;
The axis pressure chamber includes cylinder block 3;The pressure indoor includes pressure indoor upper cover 6, cylinder 12 and pedestal 13;It is described Piston rod 24 includes the body of rod 241, first piston 242 and second piston 243;
The cylinder block 3 includes first chamber;The cylinder 12 includes second chamber, third chamber and pressure communication hole 22, the second chamber and the third chamber by segregated portion every;The body of rod 241 is sequentially passed through by the first chamber The cylinder block 3, the pressure indoor upper cover 6, the second chamber, the lattice are until the third chamber;Described One piston 242 is arranged in the first chamber;The second piston 243 is arranged in the second chamber;
The cylinder cover 1 is closed with the first chamber lid, shape between the first piston 242 and the cylinder cover 1 Chamber is pressed at axis;The pressure indoor upper cover 6 is closed with the second chamber lid, the pressure indoor upper cover 6 and the second piston 243 it Between formed counter balance pocket 7;The pedestal 13 is closed with the third chamber cover, the pedestal 13, the cylinder 12 and the body of rod 241 Confining pressure chamber is formed after cooperation;The counter balance pocket 7 is connected to the confining pressure chamber by pressure communication hole 22;
The cylinder block 3 is fixed in the pressure indoor upper cover 6.
Pressure chamber structure provided by the utility model is provided with 22 peace of pressure communication hole between the body of rod 241 and cylinder 12 Weigh chamber 7, forms confining pressure self-compensating structure, ensure that the confining pressure for acting on 243 upper ring surface of second piston Yu 241 lower end surface of the body of rod It can cancel out each other, to not interfere the load of axis pressure, make it possible to realize efficient axis pressure load.
Based on this, for the utility model compared with original technology, having can be realized confining pressure self compensation, realize that efficient axis pressure adds The advantages of load.
In the optinal plan of the present embodiment, between the cylinder block 3 and the cylinder cover 1, the cylinder block 3 with It is sealed by first seal between the first piston 242, between the cylinder block 3 and the body of rod 241.
In the above-mentioned technical solutions, further, between the pressure indoor upper cover 6 and the body of rod 241, the pressure indoor Between upper cover 6 and the cylinder 12, between the second piston 243 and the cylinder 12, the body of rod 241 and the lattice Between, pass through second seal between the cylinder 12 and the pedestal 13 and seal.
In the above-mentioned technical solutions, further, the first seal is ordinary seals 23;The second seal For Special-shaped seal components 8.
Specifically, axis pressure chamber includes cylinder block 3 and cylinder cover 1, one end of cylinder block 3 is covered by cylinder cover 1 It closes, and fixed by cylinder cap attachment screw 26.Pressure indoor includes pressure indoor upper cover 6, cylinder 12 and pedestal 13;Pressure indoor upper cover 6 One end of cylinder 12 is fixed on by upper cover attachment screw 5, pedestal 13 is fixed on the other end of cylinder 12.Cylinder block 3 utilizes Oil cylinder attachment screw 25 passes through pressure indoor upper cover 6 and cylinder 12 is fixed.
Cylinder block 3 includes first chamber;Cylinder 12 includes second chamber, third chamber and pressure communication hole 22, institute the Two chambers and third chamber by segregated portion every;The body of rod 241 sequentially passes through cylinder block 3, pressure indoor upper cover by first chamber 6, second chamber, lattice are until third chamber;First piston 242 is fixed on an end of the body of rod 241;Second piston 243 are arranged on the corresponding body of rod 241 of second chamber;Another end of the body of rod 241 extends to third chamber.
Between cylinder block 3 and cylinder cover 1, between cylinder block 3 and first piston 242, cylinder block 3 and the body of rod It is connected by ordinary seals 23 between 241, wherein closed between cylinder cover 1, cylinder block 3 and first piston 242 Space is that axis presses chamber;Cylinder cover 1 is equipped with the oil cylinder B mouth 2 being connected to axis pressure chamber.First piston 242 presses the one of chamber far from axis Side surface and the oil cylinder body of rod 241, which are formed, replys chamber, and the oil cylinder A mouth 4 being connected to reply chamber is provided on the oil cylinder body of rod 241.Confining pressure Counter balance pocket 7 is formed between room upper cover 6 and second piston 243, there are two the position settings that pressure indoor upper cover 6 and the body of rod 241 cooperate Special-shaped seal components 8;The position that pressure indoor upper cover 6 and cylinder 12 cooperate is provided with a Special-shaped seal components 8;Second piston 243 with A Special-shaped seal components 8 are provided between cylinder 12;A Special-shaped seal components 8 are provided between the body of rod 241 and cylinder 12;Cylinder A Special-shaped seal components 8 are provided between 12 and pedestal 13.A confining pressure inlet and outlet 16 are additionally provided on the pedestal 13.Setting The position of Special-shaped seal components 8 is equipped with a guide sleeve 81.
The seepage velocity of Oil in Super-low Permeability is very slow, and the test process of single test requires the time in several weeks, the present embodiment Ordinary seals 23 and Special-shaped seal components 8, the reasonable employment of sealing element, so that whole equipment have been placed in many places inside pressure chamber Air-tightness is improved, especially for the test specimen of large scale, needs to use large-sized triaxial cell, at this time Special-shaped seal components 8 position in a device, it is irreplaceable to play the role of ordinary seals 23, guarantees that hydraulic oil will not leak, is entirely surveying Confining pressure and axis pressure can be maintained in the examination period.
It further include heating coil 9 in the optinal plan of the present embodiment, which is set on the outer surface of cylinder 12.
It further include test suite in the optinal plan of the present embodiment;
The test suite includes test specimen seaming chuck 21, test specimen push-down head 19 and Sample sleeve 10;
The test specimen seaming chuck 21, the test specimen push-down head 19 one end respectively with two end in contact of test specimen, contact site It is arranged in the Sample sleeve 10 with the test specimen;The other end of the test specimen seaming chuck 21 is contacted with the body of rod 241;It is described The other end of test specimen push-down head 19 is connect with the pedestal 13.
In the above-mentioned technical solutions, further, seepage flow import 14 and seepage exit 15 are provided on the pedestal 13;
Inlet ductwork 11 is provided between the seepage flow import 14 and the test specimen seaming chuck 21;
Export pipeline 17 is provided between the seepage exit 15 and the test specimen push-down head 19.
Embodiment two
Fig. 4 is second of structural schematic diagram of pressure chamber structure provided by the embodiment of the utility model.
As shown in figure 4, the pressure chamber structure provided in this embodiment, is the pressure chamber knot provided embodiment one The further improvement of structure, technical solution described in embodiment one also belong to the embodiment, the technology that embodiment one has been described Scheme is not repeated to describe.
Specifically, further including thermal insulation board 27 as shown in figure 4, provide a kind of pressure chamber structure in the present embodiment;
The thermal insulation board 27 is arranged between the cylinder block 3 and the pressure indoor upper cover 6.
At present technology do not use thermal insulation board 27 by the confining pressure chamber and axis of triaxial cell pressure chamber separate and directly to confining pressure Chamber is heated, therefore be will lead to heat and be transmitted to axis pressure chamber upwards, and especially for higher temperature, high temperature can make axis press chamber Interior hydraulic oil viscosity reduces, and influences the pressurizing performance of piston, pressure is difficult to improve, while the lower hydraulic oil of viscosity is also easy Across sealing element, the leakage of hydraulic oil is formed.Confining pressure chamber and axis pressure chamber are separated using thermal insulation board 27, avoid this unfavorable feelings The appearance of condition.
Embodiment three
As shown in figure 5, the permeability test macro includes pipeline this embodiment offers a kind of permeability test macro Gas circuit unit, temperature control unit, acquisition control unit and the pressure chamber structure;
The pipeline gas circuit unit is connect with the pressure chamber structure;The acquisition control unit and the pipeline gas circuit list Member connection;
The pipeline gas circuit unit is used to test the connection and separation of required fluid;The temperature control unit is for controlling The temperature of the pipeline gas circuit unit and the pressure chamber structure is constant;The acquisition control unit is described for acquiring and controlling Pressure information, temperature information and the flow information of pipeline gas circuit unit, the temperature control unit and the pressure chamber structure.
As shown in figure 5, in the optinal plan of the present embodiment, the pipeline gas circuit unit include upstream pressure sensor 41a, Downstream pressure sensor 41b, differential pressure pickup 40 and temperature sensor 42;
Specifically, in pipeline gas circuit unit, two mouths of three-position three-way valve A30 respectively with vacuum pump 28 and 3-position-3-way A mouth of valve B31 connects, and another mouth of three-position three-way valve B31 is connect with flowmeter 29;First gas injection pump 37 passes through second Valve 33 is connect with upstream air accumulator 39a, and upstream pressure sensor 41a is arranged on upstream inlet pipeline 11, for controlling pressure The inlet ductwork 11 being connected in power cell structure with seepage flow import 14;Second gas injection pump 38 passes through third valve 34 and downstream gas tank 39b connection, downstream pressure sensor 41b is arranged on pipeline 17 at downstream outlets, for controlling in pressure chamber structure to go out with seepage flow The export pipelines 17 of 15 connection of mouth;Differential pressure pickup 40 is provided between upstream inlet pipeline 11 and lower exit pipeline 17;Three The third mouth of position three-way valve B31 is connected on pipeline 17 at downstream outlets by the first valve 32;Confining pressure pump 44 passes through the 4th valve Door 35 is connected to confining pressure chamber;Axis press pump 43 presses chamber to be connected to by the 5th valve 36 with axis;Acquisition control unit includes acquisition control Device 45, acquisition controller 45 are connect with entire temperature control unit.
Example IV
A kind of rock seepage tests method based on permeability test macro described in embodiment three is present embodiments provided, it is main Oil in Super-low Permeability rock is tested, be included the following steps:
Step 1, test specimen is installed: test specimen 20 to be measured is toasted 24 hours in 105 DEG C of baking ovens, is packed into Sample sleeve 10 after cooling (Sample sleeve 10 is heat-shrinkable T bush);Pressure chamber's attachment screw 18 is opened, after lifting cylinder 12, the test specimen 20 of Sample sleeve 10 will be had It is placed on test specimen push-down head 19, and is partially embedded into test specimen seaming chuck 21 in Sample sleeve 10, sample is made by air-heater heating Product set 10 is in close contact with test specimen seaming chuck 21, test specimen 20 and test specimen push-down head 19;Cylinder 12 is put down, and tightens pressure chamber's connection Screw 18.
Step 2, it injects confining pressure: closing the first valve 32, the second valve 33, third valve 34 and the 5th valve 36, open 4th valve 35, the confining pressure chamber using confining pressure pump 44 by confining pressure inlet and outlet 16 to pressure chamber injects hydraulic oil, to downstream pressure Sensor 41b is shown reach target confining pressure value after, stop confining pressure pump 44, and close the 4th valve 35.
Step 3, it injects axis pressure: opening the 5th valve 36, using axis press pump 43 by oil cylinder B mouth 2 to triaxial cell Axis presses chamber to inject hydraulic oil, after upstream pressure sensor 41a shows and reaches target axis pressure value, stops axis press pump 43, and close 5th valve 36.
Step 4, it vacuumizes: using the permeability of different types of gasmetry out difference, generally use nitrogen, helium Gas, methane etc. are used as seepage flow fluid, and the permeability of test specimen, needs to seepage flow pipeline when passing through test specimen for measurement single kind gas It is vacuumized, excludes the interference of air.Open the first valve 32, the second valve 33 and third valve 34, and by 3-position-3-way Valve A30 is placed in the direction for being connected to vacuum pump 28 with three-position three-way valve B31 and passes through after opening vacuum pump 28 vacuumizes 24 hours Acquisition controller 45 confirms that the air pressure of seepage flow channel interior already close to being 0, that is, is vacuumized and met the requirements.The first valve 32 is closed, Close vacuum pump 28.
Step 5, it heats: using the intracavitary hydraulic oil of 9 heated pressure room cylinder 12 of heating coil and pressure chamber's confining pressure, to temperature After sensor 42 reaches target temperature, by control insulating box 46 and heating coil 9, pressure room temperature is made to be maintained at target temperature.
Step 6, it injects air pressure: opening the second valve 33 and third valve 34, open the first gas injection pump 37 and the second gas injection Pump 38, injects gas to upstream air accumulator 39a, downstream gas tank 39b respectively, and upstream and downstream air pressure reaches the same goal pressure After value, makes gas injection pump continuous service for a period of time, air pressure change is observed by acquisition controller 45, until test specimen reaches saturation, Upstream and downstream stable gas pressure closes third valve 34 and the second gas injection pump 38 after target pressure value.Using the first gas injection pump 37 to examination The target pulse pressure of part upstream one is then shut off the second valve 33 and the first gas injection pump 37.
Step 7, fluid permeability: after completing injection air pressure, fluid penetrates into downstream from test specimen upstream, and upstream air pressure gradually subtracts Small, downstream air pressure is gradually increased, until upstream and downstream air pressure balance.In the process, using on acquisition controller 45 in real time record The information that pressure sensor 41a, downstream pressure sensor 41b, differential pressure pickup 40 and temperature sensor 42 acquire is swum, and is stored In computer.
Step 8, it is vented: after the completion of single seepage tests, opening the first valve 32, and three-position three-way valve A30 is placed in company Open to atmosphere position is discharged the gas in seepage flow pipeline, to carry out next test.
Step 9, variable element test: for the same test specimen, sample can not torn open first, by gradually individually change axis pressure, confining pressure, The parameters such as temperature repeat step 2-8, measure permeability of the test specimen under different temperatures, axis pressure, confining pressure.
Step 10, it tears sample open: after individual sample test is fully completed, opening the first valve 32, the 4th valve 35 and the 5th valve Gas in seepage flow pipeline is discharged in door 36, and hydraulic oil returns to oil pump, opens pressure chamber's attachment screw 18, lifts pressure chamber's cylinder After 12, sample is removed, repeatable step 1-9 carries out the test of next test specimen, or directly puts down pressure chamber's cylinder 12, and tighten Pressure chamber's attachment screw 18 completes test.
Step 11, data processing can calculate permeability by following methods according to the data of record:
In formula, k is permeability (m2), c is decline of pressure coefficient, and μ is fluid coefficient of viscosity (Pas), and L is test specimen 20 Length (m), V1For the upper end conduit of test specimen 20 and the volume (m of upstream air accumulator 39a3), V2For test specimen 20 lower end conduit and under Swim the volume (m of air accumulator 39b3),pfThe average pressure (MPa) at 20 both ends of test specimen, p' after stablizing for pressure0When for on-test The air pressure (MPa) at 20 both ends of test specimen, Δ p' are pulse (MPa), p '1And p'2During respectively testing, t moment test specimen 20 Upper and lower ends pressure value (MPa).
Embodiment five
A kind of rock seepage tests method based on permeability test macro described in embodiment three is present embodiments provided, it is main Thief zone rock is tested.
Its permeability of complete Oil in Super-low Permeability rock is very low, and pulse attenuation method is suitble to measure permeability, but some Oil in Super-low Permeability rocks Stone contains crack, so that permeability greatly increases, pulse attenuation method is no longer applicable in, and steady state method should be taken to be tested.Therefore, In order to balance to the measurement of hypertonic rock, by changing some external device (ED)s, equally can be achieved to Thief zone using the pressure chamber The test of rate.
Test procedure: the step 1-5 and step 1-5 in example IV describes identical.
Step 6, air pressure is injected: when using steady state method test, it is only necessary to it is pressurizeed using the first gas injection pump 37 to upstream, downstream Directly communicated with atmosphere.Third valve 34 is closed, opens the first valve 32, the second valve 33 and the first gas injection pump 37, and will Three-position three-way valve B31 is placed in 29 access of flowmeter, adjusts pump pressure, upstream pressure sensor 41a is made to reach upstream destination pressure value.
Step 7, fluid permeability: after completing injection air pressure, fluid penetrates into the atmosphere of downstream from test specimen upstream, observes flowmeter 29, after flowmeter 29 stabilizes to definite value, upstream pressure sensor 41a, temperature sensing are recorded using acquisition controller 45 in real time The information that device 42 and flowmeter 29 acquire, and be stored in computer.
Step 8, it closes gas injection pump: after constant flow tests a period of time, the first gas injection pump 37 can be closed, complete single steady The test of state method seepage flow.
Step 9-10 is the same as the step 9-10 in example IV;
Step 11, data processing: according to the data of record, permeability can be calculated by following methods:
In formula, k is permeability (m2), Q is flow (m when flowmeter 29 is stablized3/ s), μ is fluid coefficient of viscosity (Pa S), L is 20 length (m) of test specimen, and A is 20 cross-sectional area (m of test specimen2),p1For upstream destination pressure value (Pa), p2For downstream pressure Value, i.e. atmospheric pressure.
Finally, it should be noted that the above various embodiments is only to illustrate the technical solution of the utility model, rather than it is limited System;Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art should Understand: it is still possible to modify the technical solutions described in the foregoing embodiments, or to some or all of Technical characteristic is equivalently replaced;And these are modified or replaceed, it does not separate the essence of the corresponding technical solution, and this is practical new The range of each embodiment technical solution of type.

Claims (10)

1. a kind of pressure chamber structure, which is characterized in that including axis pressure chamber, pressure indoor and piston rod;
The axis pressure chamber includes cylinder block and cylinder cover;The pressure indoor includes pressure indoor upper cover, cylinder and pedestal;It is described Piston rod includes the body of rod, first piston and second piston;
The cylinder block includes first chamber;The cylinder includes second chamber, third chamber and pressure communication hole, and described Two chambers and the third chamber by segregated portion every;The body of rod sequentially passes through the oil cylinder by the first chamber Body, the pressure indoor upper cover, the second chamber, the lattice are until the third chamber;The first piston setting exists In the first chamber;The second piston is arranged in the second chamber;
The cylinder cover and the first chamber lid close, and form axis between the first piston and the cylinder cover and press chamber; The pressure indoor upper cover and the second chamber lid close, and form counter balance pocket between the pressure indoor upper cover and the second piston; The pedestal and the third chamber cover are closed, and form confining pressure chamber after the pedestal, the cylinder and body of rod cooperation;It is described flat Weighing apparatus chamber is connected to the confining pressure chamber by pressure communication hole;
The cylinder block is fixed in the pressure indoor on lid.
2. pressure chamber structure according to claim 1, which is characterized in that further include thermal insulation board;
The thermal insulation board is arranged between the cylinder block and the pressure indoor upper cover.
3. pressure chamber structure according to claim 2, which is characterized in that the cylinder block and the cylinder cover it Between, between the cylinder block and the first piston, between the cylinder block and the body of rod pass through first seal Sealing.
4. pressure chamber structure according to claim 3, which is characterized in that between the pressure indoor upper cover and the body of rod, Between the pressure indoor upper cover and the cylinder, between the second piston and the cylinder, the body of rod and the lattice Between, pass through second seal between the cylinder and the pedestal and seal.
5. pressure chamber structure according to claim 4, which is characterized in that the first seal is ordinary seals;Institute Stating second seal is Special-shaped seal components.
6. pressure chamber structure according to claim 5, which is characterized in that further include heating coil;
The heating coil is set on the outer surface of the cylinder.
7. pressure chamber structure according to claim 6, which is characterized in that further include test suite;
The test suite includes test specimen seaming chuck, test specimen push-down head and Sample sleeve;
The test specimen seaming chuck, the test specimen push-down head one end respectively with two end in contact of test specimen, contact site and the examination Part is arranged in the Sample sleeve;The other end of the test specimen seaming chuck is contacted with the body of rod;The test specimen push-down head it is another One end is connect with the pedestal.
8. pressure chamber structure according to claim 7, which is characterized in that be provided with seepage flow import and seepage flow on the pedestal Outlet;
Inlet ductwork is provided between the seepage flow import and the test specimen seaming chuck;
Export pipeline is provided between the seepage exit and the test specimen push-down head.
9. a kind of permeability test macro, which is characterized in that the permeability test macro includes pipeline gas circuit unit, constant temperature control Unit, acquisition control unit and pressure chamber structure as claimed in claim 8 processed;
The pipeline gas circuit unit is connect with the pressure chamber structure;The acquisition control unit and the pipeline gas circuit unit connect It connects;
The pipeline gas circuit unit is used to test the connection and separation of required fluid;The temperature control unit is described for controlling The temperature of pipeline gas circuit unit and the pressure chamber structure is constant;The acquisition control unit is for acquiring and controlling the pipeline Gas circuit unit, the pressure information of the temperature control unit and the pressure chamber structure, temperature information and flow information.
10. permeability test macro according to claim 9, which is characterized in that the pipeline gas circuit unit includes upstream Pressure sensor, downstream pressure sensor, differential pressure pickup and temperature sensor.
CN201821485511.7U 2018-09-11 2018-09-11 A kind of pressure chamber structure and permeability test macro Active CN208672488U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109030318A (en) * 2018-09-11 2018-12-18 中国科学院地质与地球物理研究所 A kind of pressure chamber structure and permeability test macro
CN113811753A (en) * 2019-04-24 2021-12-17 沙特阿拉伯石油公司 Testing petrophysical properties using a three-axis pressure centrifuge apparatus

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109030318A (en) * 2018-09-11 2018-12-18 中国科学院地质与地球物理研究所 A kind of pressure chamber structure and permeability test macro
CN109030318B (en) * 2018-09-11 2024-04-02 中国科学院地质与地球物理研究所 Pressure chamber structure and permeability testing system
CN113811753A (en) * 2019-04-24 2021-12-17 沙特阿拉伯石油公司 Testing petrophysical properties using a three-axis pressure centrifuge apparatus

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