CN205089298U - Fracture type carbonate oil reservoir physical model , displacement simulation experiment device and system - Google Patents
Fracture type carbonate oil reservoir physical model , displacement simulation experiment device and system Download PDFInfo
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Abstract
The utility model relates to a fracture type carbonate oil reservoir physical model, displacement simulation experiment device and system, wherein, physical model includes: solution cavity, crack, base plate and filler, wherein, the solution cavity with the crack is arranged in on the base plate, the solution cavity with the crack is connected in an organic whole, the filler is used for the simulation the solution cavity condition of filling, physical model is provided with filling opening, oil production port and bottom water mouth. The visual displacement experimental apparatus of this fracture type oil reservoir more is close actual reservoir model, especially to solution cavity type fracture type oil reservoir, can simulate fracture's discretization distribution characteristics of. Simulation to filling the solution cavity is more practical. In addition, the detachability of fracture model has strengthened the maneuverability and the flexibility of experiment, has shortened establishment of the model of, adjustment, maintenance period, but modelling simple process reuse, greatly reduced the experiment cost.
Description
Technical field
The utility model relates to technical field of oil production engineering, particularly a kind of fractured-cavernous carbonate reservoir physical model, displacement simulation experimental facilities and system.
Background technology
Fractured-cavernous carbonate reservoir reservoir belongs to the reservoir of reworked, and due to the impact of lithology, structure and corrosion etc., the type of its reservoir space has obviously different compared with clastic reservoir rock.Hole, hole, seam are main reservoir space and flow channel, and fracture and cave reservoir has the features such as spatial stochastically distribution, configuration relation is complicated, shape dimensional variation is various.Solution cavity refers to that diameter is greater than the hole of 50mm, and dissolution pore mainly refers to the hole of diameter between 2mm to 50mm, and crack is mainly based on structure, corrosion seam, and fracture aperture is less than 1mm mostly.According to the combination that reservoir space is different, three kinds of representative reservoir types of Ordovician of Tahe oil are: slit formation, crack-hole type, Caves.Wherein, Caves reservoir is grown based on large-scale solution cavity; Crack elimination is based on fracture development, and hole, hole are grown less; Crack-hole type reservoir is then grow based on crack and corrosion hole, and large-scale solution cavity is grown less.
Caves reservoir is most important Reservoir type in local area ORDOVICIAN CARBONATE, and it is grown for feature with large-scale solution cavity, and be extraordinary hydrocarbon pore volume, solution cavity and crack are main flow channel.According to system in Tahe Oilfield statistics, the output of oil field more than 90% all comes from this type of reservoir.The feature of such reservoir hydrocarbons output is the high and stable yield or more stable of IP, and stable production period is long, and the Lower Ordovician Series of the wells such as S48, T401, T402, the TK407 in system in Tahe Oilfield four district all belongs to this type of reservoir.
The filling phenomenon of solution cavity is very general, and this is because the large scale of solution cavity and underground structure unstability cause.The charges of system in Tahe Oilfield solution cavity have three types usually, carrying type deposit, the type that collapses deposit and chemical type cement.Forefathers study and usually solution cavity are divided into full-filling, half filling and non-filling 3 kinds, wherein Tahe four district solution-cavity filling recognition result display: the solution cavity of whole fill accounts for 43% of sum, and the solution cavity of part filling accounts for 37%, and the solution cavity of substantially non-filling has accounted for 20%.The inner Filling Characteristics of its solution cavity has important production meaning.
Based on the geological structure that fracture-pore reservoir is special: seam hole is discretization distribution, solution cavity has differentiation and fills feature.The representativeness of laboratory experiment simulation model is the difficult point of such oil reservoir indoor physical simulation always, very few especially for the embodiment of the filling feature of differentiation in special model.And domestic fracture-pore reservoir part entered the exploitation middle and later periods, enter the modification scenario stage, therefore, set up representative seam hole model and relevant water drive oil, the oily experimental facilities of gas drive be necessary with urgently.
Existing fracture-pore reservoir physical model mainly comprises glass tube model, etches flat plate model, builds irregular model, rock core seam hole model etc., mostly attempt complete seam hole combined system to be made into a smaller space, thus cause that geometric similarity criterion cannot meet, complex configurations relation is ignored, finally cause simulation process serious distortion, analog result lacks directiveness.Solution cavity various shapes, Filling Characteristics complexity in oil reservoir, fracture condudtiviy difference is large, and annexation is complicated, and existing model is difficult to control in manufacturing process, experimentation very flexible.
Utility model content
For solving the problem of prior art, the utility model proposes a kind of fractured-cavernous carbonate reservoir physical model, displacement simulation experimental facilities and system.
For achieving the above object, the utility model provides a kind of fractured-cavernous carbonate reservoir physical model, and described physical model comprises:
Solution cavity, crack, substrate and filler; Wherein,
Described solution cavity and described crack are placed on described substrate, and described solution cavity and described crack are connected to one, and described filler fills situation for simulating described solution cavity;
Described physical model is provided with inlet, extraction mouth and the mouth of a river, the end.
Preferably, described solution cavity comprises solution cavity main body and cover plate, and described solution cavity main body comprises solution cavity chamber, solution cavity mould walls and crack connecting hole; Described solution cavity chamber is sealed by helicitic texture and sealing ring by described cover plate; Described crack connecting hole is arranged in described solution cavity mould walls.
Preferably, described solution cavity is connected with described crack by crack connecting hole, adopts pressure-pad connector and pressure ring seal described solution cavity and described crack to be connected in one.
Preferably, described solution cavity is regular circle shapes shape.
Preferably, described filler is quartz sand.
Preferably, described crack adopts polytetrafluoroethylmaterial material pipeline to simulate.
Preferably, described solution cavity adopts acrylic material to make.
For achieving the above object, the utility model additionally provides a kind of displacement simulation experimental facilities, carry out displacement test for physical model described above, displacement simulation experimental facilities comprises: end water device, the first device for pressure measurement, the second device for pressure measurement, source of the gas, constant flow pump, gas-flow rate controller, simulated oil container, simulated formation water receptacle, metering device; Wherein,
The mouth of a river, the end of described physical model is all connected with water device of the described end, described second device for pressure measurement;
Described constant flow pump is all connected with the entrance of described simulated oil container, the entrance of described simulated formation water receptacle, and the outlet of described simulated oil container, the outlet of described simulated formation water receptacle are all connected with the inlet of described physical model;
Described source of the gas is connected with one end of described gas-flow rate controller, and the other end of described gas-flow rate controller is connected with the inlet of described physical model;
The inlet of described physical model is connected with described first device for pressure measurement;
The extraction mouth of described physical model is connected with described metering device.
Preferably, also video camera is comprised;
Described video camera, for recording the experimentation of experimental facilities.
For achieving the above object, the utility model additionally provides a kind of displacement simulation experimental system, comprising: physical model described above and displacement simulation experimental facilities described above.
Technique scheme has following beneficial effect:
This fracture-pore reservoir visual displacement test device, closer to actual reservoir model, especially for Caves fracture-pore reservoir, can simulate the discretization distribution characteristics in seam hole.Simulation for filling solution cavity is more practical.In addition, the detachability of seam hole model strengthens operability and the flexibility of experiment, shortens the foundation of model, adjustment, maintenance period, and modelling technique is simple, can reuse, and greatly reduces experimental cost.
The utility model can be used for fracture-pore reservoir bottom water drive, filled drive, gas injection are driven, foam flooding and the research of other displacement test.The change of the index such as two-phase or multiphase fluid movement and different phase recovery ratio, moisture content, void fraction, producing pressure differential in the fracture-pore reservoir of research different structure, remaining oil distribution characteristics under research water drive, gas drive, foam flooding and other displacement modes.For fracture and vug carbonate reservoir Efficient Development provides theoretical foundation and technical support.
Accompanying drawing explanation
In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.
Fig. 1 is one of physical model structure schematic diagram of a kind of fractured-cavernous carbonate reservoir that the utility model proposes;
Fig. 2 is the physical model structure schematic diagram two of a kind of fractured-cavernous carbonate reservoir that the utility model proposes;
Fig. 3 is the solution cavity structural representation in the physical model of the fractured-cavernous carbonate reservoir that the utility model proposes;
Fig. 4 is the solution cavity structural profile schematic diagram in the physical model of the fractured-cavernous carbonate reservoir that the utility model proposes;
Fig. 5 is a kind of displacement simulation experimental facilities schematic diagram that the utility model proposes.
Accompanying drawing identifies:
1, solution cavity model cover plate, 2, solution cavity die body, 3, crack connecting hole, 4, solution cavity chamber,
5, sealing ring, 6, screw thread, 7, solution cavity mould walls, 8, the non-pack portion of solution cavity,
9, solution-cavity filling part, 10, inlet, 11, extraction mouth, 12, solution cavity,
13, large fracture is simulated, 14, the mouth of a river, the end, 15, crack in simulation, 16, simulation gap,
17. end water devices, 18, gas-flow rate controller, the 19, first device for pressure measurement, 20, camera head,
21, metering device, 22, physical model, 23, simulated formation water receptacle, 24. valves,
25, constant flow pump, 26, source of the gas, 27, simulated oil container 28, substrate
29, the second device for pressure measurement.
Detailed description of the invention
Below in conjunction with the accompanying drawing in the utility model embodiment, be clearly and completely described the technical scheme in the utility model embodiment, obviously, described embodiment is only the utility model part embodiment, instead of whole embodiments.Based on the embodiment in the utility model, those of ordinary skill in the art are not making the every other embodiment obtained under creative work prerequisite, all belong to the scope of the utility model protection.
Actual fracture-pore reservoir has complexity, particularly little solution cavity and crack be distributed in feature, due to geological knowledge precision problem, often accurately cannot obtain the distribution of seam hole.But seam hole distribution also there is certain rule, such as stitch the type in hole, cavern, large fracture, tomography character with distribution can form certain understanding.Experiment seam hole model according to geological knowledge, Geologic modeling data etc., according to similarity principle, can design the physical model of fractured-cavernous carbonate reservoir.
As shown in Figure 1, be one of the physical model structure schematic diagram of fractured-cavernous carbonate reservoir that the utility model proposes.As shown in Figure 2, the physical model structure schematic diagram two of fractured-cavernous carbonate reservoir for the utility model proposes.Described physical model comprises:
Solution cavity 12, crack, substrate 28 and filler 9; Wherein,
Described solution cavity 12 is placed on described substrate 28 with described crack, and described solution cavity 12 is connected to one with described crack, and described filler 9 fills situation for simulating described solution cavity 12;
Described physical model is provided with inlet 10, extraction mouth 11 and the mouth of a river, the end 14.
In model, solution cavity is regular circle shapes shape, and solution cavity diameter is 200mm, 300mm, 400mm, 500mm, 600mm etc., adopts acrylic material to make.Crack adopts polytetrafluoroethylmaterial material pipeline to simulate, and pipeline internal diameter is 0.25mm, 0.50mm, 0.75mm, 1.00mm, 1.50mm, 2.00mm etc.Model is made up of crack, solution cavity, substrate, is placed on substrate after seam hole connects by model, forms seam hole two-dimensional network model.
As shown in Figure 3, be the solution cavity structural representation in the physical model of fractured-cavernous carbonate reservoir that the utility model proposes.As shown in Figure 4, be the solution cavity structural profile schematic diagram in the physical model of fractured-cavernous carbonate reservoir that the utility model proposes.Solution cavity 12 comprises solution cavity main body 2 and cover plate 1, and described solution cavity main body 2 comprises solution cavity chamber 4, solution cavity mould walls 7 and crack connecting hole 3; Described solution cavity chamber 4 is sealed by screw thread 6 and sealing ring 5 by described cover plate 1; Described crack connecting hole 3 is arranged in described solution cavity mould walls 7.
In model, solution cavity and crack are all without fixed character size, and crack is divided into large, medium and small three ranks, simulate (being of a size of between 0.25mm ~ 2mm) in experimental model by changing caliber.The crack of three ranks is respectively large level crack 13, middle rank crack 16, little rank crack 15.The external diameter of simulation fracture pipeline is identical, and crack by crack connecting hole, adopts pressure ring supporting with it, pressure-pad is connected with solution cavity.Pressure-pad connector, pressure ring connector all adopt polytetrafluoroethylmaterial material to make,
Solution cavity size can according to suitable change, and the solution cavity of different size is designed with sealing ring 5 supporting with it and cover plate 1.The design for disassembly of solution cavity, can realize filling simulation in solution cavity, simulates different filling extent and different fillings.Concrete charges are determined according to survey region Filling Characteristics, generally, adopt different-grain diameter quartz sand or glass marble to simulate loose and dense pack.Solution cavity filling extent (i.e. loading) is generally determined according to geological knowledge.Once be provided with filler in solution cavity cavity, in solution cavity cavity, comprise the non-pack portion 8 of solution cavity and solution-cavity filling part 9.
This fracture-pore reservoir visual displacement test device, closer to actual reservoir model, especially for Caves fracture-pore reservoir, can simulate the discretization distribution characteristics in seam hole.Simulation for filling solution cavity is more practical.In addition, the detachability of seam hole model strengthens operability and the flexibility of experiment, shortens the foundation of model, adjustment, maintenance period, and modelling technique is simple, can reuse, and greatly reduces experimental cost.
As shown in Figure 5, a kind of displacement simulation experimental facilities schematic diagram for the utility model proposes.Experimental facilities is used for carrying out displacement test to above-mentioned physical model, and experimental facilities comprises: end water device 17, first device for pressure measurement 19, second device for pressure measurement 29, source of the gas 26, constant flow pump 25, gas-flow rate controller 18, simulated oil container 27, simulated formation water receptacle 23, metering device 21; Wherein,
The mouth of a river, the end 14 of described physical model is all connected with water device of the described end 17, described second device for pressure measurement 29; Between water device of the described end 17 and described second device for pressure measurement 29, a valve 24 is set;
Described constant flow pump 25 is all connected with the entrance of described simulated oil container 27, the entrance of described simulated formation water receptacle 23, and the outlet of described simulated oil container 27, the outlet of described simulated formation water receptacle 23 are all connected with the inlet 10 of described physical model; The exit of described simulated oil container 27, the exit of described simulated formation water receptacle 23 all arrange valve 24;
Described source of the gas 26 is connected by valve 24 one end with described gas-flow rate controller 18, and the other end of described gas-flow rate controller 18 is connected with the inlet 10 of described physical model;
The inlet 10 of described physical model is connected with described first device for pressure measurement 19;
The extraction mouth 11 of described physical model is connected with described metering device 21 by valve 24.
In addition, the displacement test device of described fracture-pore reservoir also includes the camera head 20 for recording experimentation, and it is positioned at the front end of model.
The utility model additionally provides a kind of displacement simulation experimental system, comprising: physical model described above and displacement simulation experimental facilities described above.Concrete structure situation, no longer repeats at this.
Below by specific embodiment, utility model is described.
Embodiment 1
For the present embodiment, in order to simulate, the natural bottom water drive of a kind of seam hole type carbonate reservoir is rear for exploitation, waterflooding development, note N
2drive development process, wherein water filling and gas injection adopt seam note hole to adopt mode, and namely the inlet 10 of physical model is inlet, and the extraction mouth 11 of physical model is extraction mouth, specifically comprises the steps:
(1) model connects and back-up sand
Step one, as shown in Figure 3, experimentally model connecting sewing hole model, containing 12, solution cavity in model, wherein solution cavity interior diameter is 500mm totally 2, and solution cavity interior diameter is 400mm totally 3, and solution cavity interior diameter is 300mm totally 6, and solution cavity interior diameter is 200mm totally 1.19, crack, wherein, totally 3, large level crack, totally 4, middle rank crack, 12, little rank crack.Crack adopts pressure ring to be connected with solution cavity with pressure-pad.
Step 2, solution cavity back-up sand, adopts 30 order quartz sands for filling solution cavity as filling medium.First, calculate back-up sand volume according to solution cavity volume and design loading, then measure the quartz sand of respective volume, open solution cavity cover plate, sand is inserted in solution cavity.In involved model, without filling 1, solution cavity, filling extent is 1,25% solution cavity, and filling extent is 8,50% solution cavity, and filling extent is 2,75% solution cavity.
(2) saturated oils experiment
Step one, model vacuumizes, and adopts the arbitrary inlet of vacuum pump access model or extraction mouth, closes all the other all import and export, when pressure meter is shown as-0.1MPa, close all import and export, vacuumize complete.
Step 2, saturated oils, utilizes the negative pressure saturation simulation oil formed in vacuum, and for the ease of visual observation, experiment simulated oil adopts the process of soudan III reagent dyeing.In order to increase the speed of saturated oils, adopting constant flow pump 25 simulated oil to be pumped in physical model 22, opening constant flow pump 25-simulated oil container 27-physical model 22 pipeline, start saturated oils, record constant flow pump integrated flow, is saturated oil mass, until whole model all saturated complete till.
(3) bottom water drive is for experiment
Open inlet 10 and the extraction mouth 11 of seam hole model, access metering device 21, opens the mouth of a river 14 pipeline at the bottom of end water device 17-physical model, opens experiment camera head 20, open the second device for pressure measurement 29 connected with the mouth of a river, the end 14, start bottom water drive for experiment.In experimentation, moisture content, the model bottom water drive of real time record inlet 10 and extraction mouth 11 are stitched bottom water drive in the model of hole replace process for pressure, videographs.When the moisture content of arbitrary mouthful in inlet 10 with extraction mouth 11 is greater than 98%, close corresponding mouth, until inlet 10 and extraction mouth 11 are when all moisture content all reaches 98%, bottom water drive terminates for experiment.
This experiment can obtain specific fracture-pore reservoir bottom water drive for bottom water drive in process for pressure reduction change, and inlet 10 and extraction mouth 11 water breakthrough time, moisture content, production rate, production fluid speed, oil recovery, bottom water drive are for remaining oil distribution etc.
(4) displacement in flooding experiment
For ease of model visualization, inject hydromining methylene blue staining.In the injecting process, end water passage stays open, and opens the mouth of a river 14 pipeline at the bottom of end water device 17-physical model.Open constant flow pump 25-simulated formation water receptacle 23-physical model inlet 10 pipeline, open physical model extraction mouth 11-metering device 21 pipeline, open experiment camera head 20, open the first device for pressure measurement 19 connected with the mouth of a river, the end 14 and inlet 10, according to the waterflood injection rate of setting, start displacement in flooding experiment, the moisture content of real time record extraction mouth 11, model displacement in flooding pressure, bottom water drive are for pressure, and videograph stitches displacement in flooding process in the model of hole.When extraction mouth 11 moisture content is greater than 98%, close extraction mouth, displacement in flooding experiment terminates.
This experiment can obtain specific fracture-pore reservoir (seam note hole is adopted) under specific injection mode, displacement pressure reduction change in displacement in flooding process, extraction mouth moisture content, production rate, production fluid speed, oil recovery, displacement in flooding remaining oil distribution etc.
(5) N is noted
2displacement test
Note N
2in process, end water passage stays open, and opens the mouth of a river 14 pipeline at the bottom of end water device 17-physical model, opens N
2source of the gas 26-gas-flow rate controller 18-physical model inlet 10 pipeline, open physical model extraction mouth 11-metering device 21 pipeline, open experiment camera head 20, open the first device for pressure measurement 19 connecting and be connected with inlet 10 with second device for pressure measurement 29 at the mouth of a river, the end 14, according to the gas injection speed of setting, start gas injection displacement test, moisture content, the void fraction of real time record extraction mouth 11, model gas injection displacement pressure, bottom water drive are for pressure, and videograph stitches gas injection displacement process in the model of hole.When extraction mouth 11 moisture content is greater than 98%, close extraction mouth, gas injection displacement test terminates.
This experiment can obtain specific fracture-pore reservoir (seam note hole is adopted) under specific injection mode, displacement pressure reduction change in gas injection displacement process, extraction mouth moisture content, void fraction, production rate, production fluid speed, oil recovery, gas injection displacement remaining oil distribution etc.
Embodiment 2
For the present embodiment for the natural bottom water drive of simulation a kind of seam hole type carbonate reservoir for after exploitation, waterflooding development and note N
2drive development process, wherein water filling and gas injection adopt note hole, hole to adopt mode, and namely physical model inlet 10 is inlet, and physical model extraction mouth 11 is extraction mouth, specifically comprises the steps:
(1) model connects and back-up sand
Step one, as shown in Figure 4, experimentally model connecting sewing hole model, containing 15, solution cavity in model, wherein solution cavity interior diameter is 500mm totally 4, and solution cavity interior diameter is 400mm totally 1, and solution cavity interior diameter is 300mm totally 10, and solution cavity interior diameter is 200mm totally 1.30, crack, totally 6, its middle and big class crack, totally 24, little rank crack.Crack adopts pressure ring to be connected with solution cavity with pressure-pad.
Step 2, solution cavity back-up sand, adopts 30 order quartz sands for filling solution cavity as filling medium.First, calculate back-up sand volume according to solution cavity volume and design loading, then measure the quartz sand of respective volume, open solution cavity cover plate, sand is inserted in solution cavity.In involved model, filling extent is 1,25% solution cavity, and filling extent is 12,50% solution cavity, and filling extent is 2,75% solution cavity.
(2) saturated oils experiment
Step one, model vacuumizes, and adopts the arbitrary inlet of vacuum pump access model or extraction mouth, closes all the other all import and export, when pressure meter is shown as-0.1MPa, close all import and export, vacuumize complete.
Step 2, saturated oils, utilizes the negative pressure saturation simulation oil formed in vacuum, and for the ease of visual observation, experiment simulated oil adopts the process of soudan III reagent dyeing.In order to increase the speed of saturated oils, adopting constant flow pump 25 simulated oil to be pumped in physical model 22, opening constant flow pump 25-simulated oil container 27-physical model 22 pipeline, start saturated oils, record constant flow pump integrated flow, is saturated oil mass, until whole model all saturated complete till.
(3) bottom water drive is for experiment
Open physical model inlet 10 and extraction mouth 11, access metering device 21, opens the mouth of a river 14 pipeline at the bottom of end water device 17-physical model, opens experiment camera head 20, opens the second device for pressure measurement 29 connected with the mouth of a river, the end 14, starts bottom water drive for experiment.In experimentation, moisture content, the model bottom water drive of real time record extraction mouth 11 and inlet 10 are stitched bottom water drive in the model of hole replace process for pressure, videographs.When arbitrary mouthful of moisture content is greater than 98% in extraction mouth 11 with inlet 10, close corresponding mouth, until when extraction mouth 11 all reaches 98% with the equal moisture content of inlet 10, bottom water drive terminates for experiment.
This experiment can obtain specific fracture-pore reservoir bottom water drive for bottom water drive in process for pressure reduction change, and the water breakthrough time of extraction mouth 11 and inlet 10, moisture content, production rate, production fluid speed, oil recovery, bottom water drive are for remaining oil distribution etc.
(4) displacement in flooding experiment
For ease of model visualization, inject hydromining methylene blue staining.In the injecting process, end water passage stays open, and opens the mouth of a river 14 pipeline at the bottom of end water device 17-physical model.Open constant flow pump 25-Simulated Water container 23-physical model inlet 10 pipeline, open physical model extraction mouth 11-metering device 21 pipeline, open experiment camera head 20, open the first device for pressure measurement 19 connecting and be connected with inlet 10 with second pressure apparatus 29 at the mouth of a river, the end 14, according to the waterflood injection rate of setting, start displacement in flooding experiment, the moisture content of real time record extraction mouth 11, model displacement in flooding pressure, bottom water drive are for pressure, and videograph stitches displacement in flooding process in the model of hole.When extraction mouth 11 moisture content is greater than 98%, close extraction mouth, displacement in flooding experiment terminates.
This experiment can obtain specific fracture-pore reservoir (note hole, hole is adopted) under specific injection mode, displacement pressure reduction change in displacement in flooding process, extraction mouth moisture content, production rate, production fluid speed, oil recovery, displacement in flooding remaining oil distribution etc.
(5) N is noted
2displacement test
Note N
2in process, end water passage stays open, and opens the mouth of a river 14 pipeline at the bottom of end water device 17-physical model, opens N
2source of the gas 26-gas-flow rate controller 18-physical model inlet 10 pipeline, open physical model extraction mouth 11-metering device 21 pipeline, open experiment camera head 20, open the first device for pressure measurement 19 connecting and be connected with inlet 10 with second pressure apparatus 29 at the mouth of a river, the end 14, according to the gas injection speed of setting, start gas injection displacement test, moisture content, the void fraction of real time record extraction mouth 11, model gas injection displacement pressure, bottom water drive are for pressure, and videograph stitches gas injection displacement process in the model of hole.When extraction mouth 11 moisture content is greater than 98%, close extraction mouth, gas injection displacement test terminates.
This experiment can obtain specific fracture-pore reservoir (note hole, hole is adopted) under specific injection mode, displacement pressure reduction change in gas injection displacement process, extraction mouth moisture content, void fraction, production rate, production fluid speed, oil recovery, gas injection displacement remaining oil distribution etc.
For physical model, can change with extraction mouth 11 for the mouth of a river 14, inlet 10 at the bottom of different seam hole models.When simulating bottom water drive for experiment, end water is injected by the mouth of a river, the end 14, and inlet 10 and extraction mouth 11 all can be used as extraction mouth.When simulating water filling, gas injection or noting foam displacement test, end water can be opened and closedown as required, and inlet 10 can be selected for inlet, and extraction mouth 11 is that extraction mouth or inlet 10 are extraction mouth, extraction mouth 11 is inlet, forms a note one and adopts simulation.When to adopt mouth be many mouthfuls to note, many notes can be realized and adopt simulation more.
This experimental facilities can be used for fracture-pore reservoir bottom water drive, filled drive, gas injection are driven, foam flooding and the research of other displacement test.The change of the index such as two-phase or multiphase fluid movement and different phase recovery ratio, moisture content, void fraction, producing pressure differential in the fracture-pore reservoir of research different structure, remaining oil distribution characteristics under research water drive, gas drive, foam flooding and other displacement modes.For fracture and vug carbonate reservoir Efficient Development provides theoretical foundation and technical support.
Above-described detailed description of the invention; the purpose of this utility model, technical scheme and beneficial effect are further described; be understood that; the foregoing is only detailed description of the invention of the present utility model; and be not used in restriction protection domain of the present utility model; all within spirit of the present utility model and principle, any amendment made, equivalent replacement, improvement etc., all should be included within protection domain of the present utility model.
Claims (10)
1. a fractured-cavernous carbonate reservoir physical model, is characterized in that, described physical model comprises:
Solution cavity, crack, substrate and filler; Wherein,
Described solution cavity and described crack are placed on described substrate, and described solution cavity and described crack are connected to one, and described filler fills situation for simulating described solution cavity;
Described physical model is provided with inlet, extraction mouth and the mouth of a river, the end.
2. physical model as claimed in claim 1, it is characterized in that, described solution cavity comprises solution cavity main body and cover plate, and described solution cavity main body comprises solution cavity chamber, solution cavity mould walls and crack connecting hole; Described solution cavity chamber is sealed by helicitic texture and sealing ring by described cover plate; Described crack connecting hole is arranged in described solution cavity mould walls.
3. physical model as claimed in claim 2, is characterized in that, described solution cavity is connected with described crack by crack connecting hole, adopts pressure-pad connector and pressure ring seal described solution cavity and described crack to be connected in one.
4. physical model as claimed in claim 1, it is characterized in that, described solution cavity is regular circle shapes shape.
5. physical model as claimed in claim 1, it is characterized in that, described filler is quartz sand.
6. physical model as claimed in claim 1, is characterized in that, described crack adopts polytetrafluoroethylmaterial material pipeline to simulate.
7. physical model as claimed in claim 1, is characterized in that, described solution cavity adopts acrylic material to make.
8. a displacement simulation experimental facilities, it is characterized in that, for carrying out displacement test to the physical model described in the arbitrary claim of claim 1 ~ 7, displacement simulation experimental facilities comprises: end water device, the first device for pressure measurement, the second device for pressure measurement, source of the gas, constant flow pump, gas-flow rate controller, simulated oil container, simulated formation water receptacle, metering device; Wherein,
The mouth of a river, the end of described physical model is all connected with water device of the described end, described second device for pressure measurement;
Described constant flow pump is all connected with the entrance of described simulated oil container, the entrance of described simulated formation water receptacle, and the outlet of described simulated oil container, the outlet of described simulated formation water receptacle are all connected with the inlet of described physical model;
Described source of the gas is connected with one end of described gas-flow rate controller, and the other end of described gas-flow rate controller is connected with the inlet of described physical model;
The inlet of described physical model is connected with described first device for pressure measurement;
The extraction mouth of described physical model is connected with described metering device.
9. displacement simulation experimental facilities as claimed in claim 8, is characterized in that, also comprise video camera;
Described video camera, for recording the experimentation of experimental facilities.
10. a displacement simulation experimental system, is characterized in that, comprising: the physical model as described in claim as arbitrary in claim 1 ~ 7 and the displacement simulation experimental facilities as described in claim as arbitrary in claim 8 ~ 9.
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| CN105178926A (en) * | 2015-10-28 | 2015-12-23 | 中国石油大学(北京) | Fracture-cave carbonate reservoir physical model and displacement simulation experimental device and system |
| CN106703764A (en) * | 2016-12-01 | 2017-05-24 | 滨州学院 | Pore-level simulation experiment device for alternately displacing oil by microorganisms and air in porous media |
| CN109162709A (en) * | 2018-09-05 | 2019-01-08 | 中国石油大学(北京) | A kind of preparation method and application of hole type carbonate reservoir physical analogy sample |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105178926A (en) * | 2015-10-28 | 2015-12-23 | 中国石油大学(北京) | Fracture-cave carbonate reservoir physical model and displacement simulation experimental device and system |
| CN106703764A (en) * | 2016-12-01 | 2017-05-24 | 滨州学院 | Pore-level simulation experiment device for alternately displacing oil by microorganisms and air in porous media |
| CN109162709A (en) * | 2018-09-05 | 2019-01-08 | 中国石油大学(北京) | A kind of preparation method and application of hole type carbonate reservoir physical analogy sample |
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