CN209640100U - Liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system - Google Patents
Liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system Download PDFInfo
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- CN209640100U CN209640100U CN201920428119.7U CN201920428119U CN209640100U CN 209640100 U CN209640100 U CN 209640100U CN 201920428119 U CN201920428119 U CN 201920428119U CN 209640100 U CN209640100 U CN 209640100U
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- copper sheathing
- cylinder
- clamper
- clamper cylinder
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- RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 claims abstract description 109
- 229910052802 copper Inorganic materials 0.000 claims abstract description 109
- 239000010949 copper Substances 0.000 claims abstract description 109
- 230000036316 preload Effects 0.000 claims abstract description 48
- 238000010438 heat treatment Methods 0.000 claims abstract description 17
- 238000007789 sealing Methods 0.000 claims description 62
- 238000004826 seaming Methods 0.000 claims description 32
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 24
- 238000012360 testing method Methods 0.000 claims description 23
- 230000006835 compression Effects 0.000 claims description 13
- 238000007906 compression Methods 0.000 claims description 13
- 230000002093 peripheral effect Effects 0.000 claims description 12
- 239000000945 filler Substances 0.000 claims description 7
- 238000012544 monitoring process Methods 0.000 claims description 7
- 239000003208 petroleum Substances 0.000 claims description 6
- 230000037452 priming Effects 0.000 claims description 6
- 238000004064 recycling Methods 0.000 claims description 3
- 239000011435 rock Substances 0.000 abstract description 23
- 238000005336 cracking Methods 0.000 abstract description 4
- 239000003566 sealing material Substances 0.000 abstract 1
- 238000010586 diagram Methods 0.000 description 8
- 238000000034 method Methods 0.000 description 6
- 238000003780 insertion Methods 0.000 description 5
- 230000037431 insertion Effects 0.000 description 5
- 238000010276 construction Methods 0.000 description 4
- 238000011161 development Methods 0.000 description 4
- 230000000694 effects Effects 0.000 description 4
- 239000012530 fluid Substances 0.000 description 4
- 238000002347 injection Methods 0.000 description 4
- 239000007924 injection Substances 0.000 description 4
- 238000009434 installation Methods 0.000 description 4
- OKTJSMMVPCPJKN-UHFFFAOYSA-N Carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 description 3
- 229910052799 carbon Inorganic materials 0.000 description 3
- 230000005489 elastic deformation Effects 0.000 description 3
- 238000011160 research Methods 0.000 description 3
- 238000003860 storage Methods 0.000 description 3
- 230000008878 coupling Effects 0.000 description 2
- 238000010168 coupling process Methods 0.000 description 2
- 238000005859 coupling reaction Methods 0.000 description 2
- 230000000977 initiatory effect Effects 0.000 description 2
- 238000011900 installation process Methods 0.000 description 2
- 238000002955 isolation Methods 0.000 description 2
- 230000035882 stress Effects 0.000 description 2
- 239000010963 304 stainless steel Substances 0.000 description 1
- 229910000589 SAE 304 stainless steel Inorganic materials 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 238000005266 casting Methods 0.000 description 1
- 230000001808 coupling effect Effects 0.000 description 1
- 239000013078 crystal Substances 0.000 description 1
- 238000013461 design Methods 0.000 description 1
- 239000006185 dispersion Substances 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000002474 experimental method Methods 0.000 description 1
- 239000010438 granite Substances 0.000 description 1
- 239000007788 liquid Substances 0.000 description 1
- 238000004321 preservation Methods 0.000 description 1
- 238000003825 pressing Methods 0.000 description 1
- 229920002545 silicone oil Polymers 0.000 description 1
- 239000000243 solution Substances 0.000 description 1
- 229910001220 stainless steel Inorganic materials 0.000 description 1
- 239000010935 stainless steel Substances 0.000 description 1
- 239000004575 stone Substances 0.000 description 1
- 238000010998 test method Methods 0.000 description 1
- 230000008646 thermal stress Effects 0.000 description 1
- 230000000930 thermomechanical effect Effects 0.000 description 1
- 239000003643 water by type Substances 0.000 description 1
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Abstract
The utility model discloses a kind of liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing systems.Clamper in fracturing system includes clamper cylinder, clamper cylinder top is arranged upper preload housing between clamper cylinder inboard wall and copper sheathing outer wall, clamper cylinder lower part covers between clamper cylinder inboard wall and copper sheathing outer wall sets preload housing, and the lower limit end face last week for pre-tightening housing towards copper sheathing positive stop lug boss upper surface will pre-tighten compressed spring to distribution;In the case where upper preload housing blocks copper sheathing top, pre-tightens and provide axial pretightening tension to copper sheathing after compressed spring is compressed;The pretightning force that compressed spring provides is pre-tightened after high-temperature heating and is greater than core relative to copper sheathing along axial stiction, is avoided copper sheathing generation axial retraction or fold softening from causing to rupture, has been prevented leakage.The utility model is directed to small rock, and sealing material and structure meet high temperature and high pressure environment, can study the hydrofracturing initial cracking pressure and crack extended attribute of complete core and the core containing natural fissure under hot conditions.
Description
Technical field
The utility model relates to a kind of liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing systems, belong to dry-hot-rock geothermal exploitation field.
Background technique
Hot dry rock (HDR) refers to that preservation is not present or on a small quantity in below ground 3-10km, 150-650 DEG C of temperature and inside
There are the High temperature rocks of fluid (predominantly rotten class and crystal class rock mass), and hot dry rock has the characteristics that fine and close, hyposmosis, commonly
Exploitation is difficult to realize, and enhanced geothermal system (EGS) is the major technique of current hot dry rock energy development engineering, with ground hot-activity
A series of problems, such as purpose pushes, the basic research of EGS system and its engineer application becomes the emerging of recent domestic research
Hot spot.
The step of artificial storage fluid layer construction is EGS system most critical, it is required that have between heat transport fluid and high heat rock mass
Sufficiently large heat exchange area, currently, generally using huge hydrofracturing skill in the construction that high heat rock mass manually stores up fluid layer
The problem of art, the hydrofracturing engineering under high-temperature high-pressure state is an extremely complex multiphase medium multi- scenarios method, core
Heart problem in science is the fault mechanics behavior of the high temperature and pressure rock mass under Thermal-mechanical Coupling effect, including temperature, pressure, rock rock
Property, the influence to hydrofracturing crack initiation and crack propagation law such as rock homogenieity, it is necessary to pass through experimental study, grasp thermo-mechanical Coupled
Cooperate the characteristic and rule of lower high temperature and pressure rock mass hydrofracturing, the construction of layer is stayed for storage in high heat rock mass underground heat exploitation engineering
Engineering provides theoretical foundation and guidance, but less for the correlation test equipment development of underground heat research at present.
Currently both at home and abroad for the development of hydrofracturing device mainly for oil field and cbm development field, use
Temperature is mostly 200-300 DEG C, and the pressure break of the pressure break of geothermal exploitation and oil field has essential difference, is mainly reflected in underground heat
The pressure break in field is faced with high temperature (0-600 DEG C), high pressure (0-60MPa) environment, the transmission medium of experimental rig under high temperature and pressure
The problems such as selection, heating method, sealing structure always technical problem.On the one hand, the isolation copper sheathing of hydrofracturing device is in height
The ductility of (especially 300 DEG C or more) is in non-linear increase under the conditions of temperature, and copper sheathing is very easy to generation fold and ruptures and cause leakage
Liquid leads to the failure of an experiment;On the other hand, existing hydrofracturing device spininess is to large-scale rock sample, and single test it is cumbersome,
Higher cost.
Utility model content
In view of the above-mentioned problems of the prior art, the purpose of the utility model is to provide a kind of liquid-leakage preventing high-temperature high pressure waters
Fracturing system is pressed, can be avoided isolation copper sheathing because fold rupture occurs for high temperature and pressure leads to leakage, and it is easy to operate, cost is relatively low,
And be conducive to study the initial cracking pressure and crack propagation law of the rock hydrofracturing under different condition.
A kind of liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing that in order to achieve the above purposes, the technical solution adopted by the utility model is:
System, including clamper, the clamper include the clamper cylinder being vertically arranged, and are coaxially set in the clamper cylinder
There is a copper sheathing, enclosing for pressure oil can be infused externally to the confining pressure chamber between clamper cylinder and copper sheathing by being equipped in clamper barrel wall
Pressure injection oilhole, a seaming chuck and clamper cylinder are coaxially inserted from above into copper sheathing, a lower end cap and clamper cylinder coaxially from
Lower section is inserted into copper sheathing, and core is equipped in the space that seaming chuck, lower end cap and copper sheathing surround,
Clamper cylinder top is arranged on one between clamper cylinder inboard wall and copper sheathing outer wall and pre-tightens housing, copper sheathing
Pass through axial clamping structure cooperation with upper preload housing to be connected together;Clamper cylinder lower part is in clamper cylinder inboard wall
It is arranged between copper sheathing outer wall and pre-tightens housing, and copper sheathing lower loop is equipped with positive stop lug boss, the lower preload around peripheral surface
Housing towards positive stop lug boss upper surface limit end face last week to preload compressed spring is distributed with, pre-tighten the both ends of compressed spring
Respectively against limit end face and positive stop lug boss upper surface;
The seaming chuck includes pressure head top, pressure head ontology and the pressure head lower part for going deep into copper sheathing, pressure head lower part from top to bottom
Radial dimension is greater than the radial dimension in the middle part of pressure head, and sealing pre-tightening sleeve is inserted in seaming chuck from top on one and its lower end edge axially pushes up
Firmly pressure head lower part, the lower end surface of the upper sealing pre-tightening sleeve are equipped with a sealing ring I, and the lower outer peripheral surface of upper sealing pre-tightening sleeve
It is fitted closely with copper sheathing inner surface;One pretension bolt is axially set in the upper of pressure head top parallel across screw-tightened with seaming chuck
It pre-tightens pressure cap and withstands the upper surface of sealing pre-tightening sleeve;One upper cover covers on upper sealing pre-tightening sleeve and is connected by connection bolt
The upper surface of clamper cylinder is connected to, along it axially through being equipped with inlet pipeline in the seaming chuck;
The lower end cap includes plug lower part and the upper part of the plug for going deep into copper sheathing, and the upper part of the plug radial dimension is greater than under plug
Portion's radial dimension, once pre-tightens that inner sleeve is inserted in lower end cap from below and the upper part of the plug, the lower preload along axial direction are withstood in the upper end
The upper surface of inner sleeve is equipped with a sealing ring II, and the lower peripheral surface for pre-tightening inner sleeve is fitted closely with copper sheathing inner surface;Once seal
Headgear is bolted to the lower end surface of clamper cylinder on plug lower part and through connection;It is passed through in the lower end cap along its axial direction
Logical to be equipped with seepage flow water outlet channel, the position that the clamper cylinder is connected with upper cover, lower head is all equipped with sealing structure;
The seaming chuck upper surface is contacted with the press member of a servo-hydraulic testing machine, and the inlet pipeline is external to perseverance
Constant current priming device is pressed, seepage flow water outlet channel is connected to water recycling bins by return pipe, and clamper cylinder is coated with outside one
Heating structure, the confining pressure oil filler point are external to oiling device by petroleum pipeline.
Above-mentioned constant pressure and flow priming device includes constant pressure and flow twin cylinder pump, the water inlet and the water capacity of constant pressure and flow twin cylinder pump
Device is connected, and the water outlet of constant pressure and flow twin cylinder pump is connect by outlet pipe with inlet pipeline, and outlet pipe is equipped with for monitoring
The pressure gauge II of pressure.
The oiling device is constant pressure and flow single cylinder filling pump;External heating structure is electric heater, and on petroleum pipeline
Equipped with the pressure gauge I for monitoring confining pressure.
As a preferred scheme, the cylinder lower inner diameter of the clamper cylinder is greater than on the cylinder of clamper cylinder
Portion's outer diameter.The positive stop lug boss of lower preload housing and more large end face size with more large area limit end face can be accommodated, thus
It can according to need the major diameter spring that installation is enough to provide bigger pretightning force, greater number can also be installed on limit end face
Preload compressed spring, provide bigger pretensioning effect, for copper sheathing to meet different requirements.
Preferably, the axial clamping structure includes being located at the spacing block set of copper sheathing upper end periphery and axially engaging with it to set
In the upper fixture block for pre-tightening housing inner ring lower part.When applying pretightning force in installation process, when on copper sheathing upper surface and clamper cylinder
When end face is concordant, by between upper preload housing clamper cylinder inboard wall placed from above and copper sheathing outer wall, when merging, makes on copper sheathing
The spacing block set of periphery is held mutually to be staggered with the upper fixture block for pre-tightening housing inner ring, pre-tightening housing in rotation after merging makes fixture block along axis
Avoid copper sheathing integrally axially downward to spacing block set is blocked.Compressed spring is pre-tightened at this time is in compressive state and to limit
Boss upper surface applies downward pretightning force, to pre-tighten to copper sheathing.
Further, the lower inner ring for pre-tightening housing pre-tightens housing instantly and covers in copper around multiple double wedges are distributed with
When putting on, each double wedge withstands the outer peripheral surface of copper sheathing.On the one hand the multiple double wedges for being distributed setting can position lower preload housing
Position, there is sliding relative to copper sheathing radially after avoiding it from positioning;On the other hand, when pre-tightening housing under installation, double wedge
It can be staggered with spacing block set and guarantee that lower preload housing can cover on copper sheathing from top to bottom above copper sheathing.
As a preferred scheme, the upper cover is arranged back to the upper surface of clamper cylinder around upper sealing preload
There is annular groove I, the upper envelope pressure cap that an end face is equipped with sealing ring is covered on upper sealing pre-tightening sleeve and is embedded in annular groove I, and upper envelope
Pressure cap is connect by screw with upper cover.Upper envelope pressure cap equipped with sealing ring can provide better seal, effectively avoid pressure
Oil oozes out between upper cover and sealing pre-tightening sleeve.
As a preferred scheme, the lower head is equipped with annular around lower end cap back to the lower end surface of clamper cylinder
Slot II, an end face is equipped in the lower sealing compression ring insertion annular groove II of sealing ring, and lower sealing compression ring passes through screw under
End socket connection.Lower sealing compression ring comprising sealing ring can further provide for better seal, effectively avoid pressure oil under
It is oozed out between end socket and lower end cap.
Preload compressed spring be high stiffness coefficient spring, totally eight, the compressed conjunction of the lower eight preload compressed springs of room temperature
Force value provides axial pre-tightening tension for copper sheathing, and copper sheathing is made to be in elastic deformation stage;After high-temperature heating, pre-tighten compressed spring after
It is continuous that axial pre tightening force is provided, and the resultant force value of axial pre tightening force is greater than the stiction between core face and copper sheathing inner surface,
So as to avoid copper sheathing from occurring to extend and Folding Deformation rupture after high-temperature heating, the generation of the phenomenon of leakage is prevented.
Compared with the existing technology, the utility model has the advantage that
(1) the utility model is directed to small rock (φ 50*100mm), and one people of single test can carry out, easy to operate,
Cost is relatively low for single test.
(2) the utility model design is rigorous, is all equipped with stone at the position that clamper cylinder is connected with upper cover, lower head
Black sealing ring, and in the seaming chuck for protruding into copper sheathing, be provided on lower end cap multiple-sealed, sealing structure is reasonable, and has resistance to height
The feature of temperature also can guarantee that sealing is effective under the conditions of high temperature and pressure test;
Under room temperature, in the case where upper preload housing blocks copper sheathing top, copper sheathing is withstood after pre-tightening compressed spring compression
Positive stop lug boss provides axial pre-tightening tension for copper sheathing, and copper sheathing is made to be in elastic deformation stage;After high-temperature heating, compression bullet is pre-tightened
Spring continues as copper sheathing and provides axial pretightening pulling force, and the resultant force value of its axial pre tightening force provided is greater than in core face and copper sheathing
Stiction between surface prevents so as to avoid copper sheathing from occurring to extend and Folding Deformation rupture after high-temperature heating
The generation of the phenomenon of leakage ensure that success of the test rate.
(3) through actual tests, the utility model test temperature is room temperature to 400 DEG C, pressure resistance 60MPa, energy under test temperature
Enough high temperature high voltage resistants can be easy to monitoring and obtain the initial cracking pressure of core, and it is high to be conducive to study high temperature under Thermal-mechanical Coupling acts on
Press fault mechanics behavior, including temperature, pressure, rock lithology, rock homogenieity etc. of rock mass to hydrofracturing initial cracking pressure and
The influence of crack propagation law;And then be conducive to grasp characteristic and rule that Thermal-mechanical Coupling acts on lower high temperature and pressure rock mass hydrofracturing
Rule stays the construction engineering of layer to provide theoretical foundation and guidance for storage in high heat rock mass underground heat exploitation engineering.
Detailed description of the invention
Fig. 1 is the schematic diagram of the utility model;
Fig. 2 is the structural schematic diagram for the liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing clamper that the utility model includes;
Fig. 3 is the seaming chuck schematic diagram in Fig. 2;
Fig. 4 is the clamper cylinder schematic diagram in Fig. 2;
Fig. 5 is the schematic diagram of the upper preload housing in Fig. 2;
Fig. 6 is the copper sheathing schematic diagram in Fig. 2;
Fig. 7 is lower preload housing and preload compressed spring scheme of installation in Fig. 2;
Fig. 8 is the lower end cap schematic diagram in Fig. 2;
Fig. 9 is the schematic diagram for the auxiliary mounting ring used when the utility model installation;
Figure 10 is that the pressure water pressure monitored under 200 DEG C, 360 DEG C, 450 DEG C of test temperature respectively changes over time
Curve;
In figure, 1. seaming chucks;1-1. exports inserted block;1-2. inlet pipeline;1-3. pressure head top;1-4. pressure head ontology;1-
5. pressure head lower part;2. upper preload pressure cap;3. pre-tightening sleeve is sealed on;3-1. sealing ring I, 4. pretension bolts;5. pressure cap is sealed on;On 6.
End socket;8. carbon seal ring;
9. clamper cylinder;9-1. cylinder top;9-2. cylinder lower part;9-3. confining pressure oil filler point;10. housing is pre-tightened on;
10-1. fixture block;10-2. rotational positioning hole;11. lower pre-tighten housing;11-1. limiting end face;11-2. spring mounting hole;11-3. is convex
Tooth;12. copper sheathing;12-1. spacing block set;12-2. positive stop lug boss;13. core;14. pre-tightening compressed spring;15. mounting ring is assisted,
15-1. positioning convex platform;
16. lower pre-tighten inner sleeve;16-1. sealing ring II;17. lower end cap;17-1. seepage flow water outlet channel;17-2. on plug
Portion;17-3. plug lower part;18. lower head;19. lower seal compression ring;
20. constant pressure and flow twin cylinder pump;20-1. pressure gauge II, 21. constant pressure and flow single cylinder filling pumps;22. servo-hydraulic is tested
Machine;23. outside heating structure;24. return pipe;25. pressure gauge I.
Specific embodiment
The utility model is described in further detail with reference to the accompanying drawing.
As shown, a kind of liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system, including clamper, the clamper include vertical
The clamper cylinder 9 of setting is coaxially equipped with a copper sheathing 12 in the clamper cylinder 9, and being equipped in 9 wall of clamper cylinder can
Externally to the confining pressure oil filler point 9-3 of the confining pressure chamber note pressure oil between clamper cylinder 9 and copper sheathing 12, a seaming chuck 1 and folder
Holder cylinder 9 is coaxially inserted from above into copper sheathing 12, a lower end cap 17 and the coaxial insertion copper sheathing 12 from below of clamper cylinder 9
In, core 13 is equipped in the space that seaming chuck 1, lower end cap 17 and copper sheathing 12 surround,
9 top of clamper cylinder is arranged on one between 12 outer wall of 9 inner wall of clamper cylinder and copper sheathing and pre-tightens housing
10, copper sheathing 12 passes through axial clamping structure cooperation with upper preload housing 10 and is connected together;9 lower part of clamper cylinder is pressing from both sides
Preload housing 11 is arranged between 12 outer wall of 9 inner wall of holder cylinder and copper sheathing, and 12 lower loop of copper sheathing is equipped with around peripheral surface
Positive stop lug boss 12-2, the lower preload housing 11 are set towards circumferentially distributed on the limit end face 11-1 of the upper surface positive stop lug boss 12-2
Have and pre-tighten compressed spring 14, pre-tightens in the spring mounting hole 11-2 that 14 one end of compressed spring is fixed on limit end face 11-1, and
The both ends of compressed spring 14 are pre-tightened respectively against limit end face 11-1 and the upper surface positive stop lug boss 12-2;
The seaming chuck 1 includes pressure head top 1-3, pressure head ontology 1-4 and the pressure head lower part for going deep into copper sheathing 12 from top to bottom
1-5, pressure head lower part 1-5 radial dimension are greater than the radial dimension in the middle part of pressure head, and sealing pre-tightening sleeve 3 is inserted in seaming chuck from top on one
1 and its lower end edge axially withstand pressure head lower part 1-5, the lower end surface of the upper sealing pre-tightening sleeve 3 is equipped with I 3-1 of a sealing ring, and on
The lower outer peripheral surface of sealing pre-tightening sleeve 3 is fitted closely with 12 inner surface of copper sheathing;One pretension bolt 4 is axial parallel with seaming chuck 1
The upper preload pressure cap 2 of pressure head top 1-3 is set in across screw-tightened and withstands the upper surface of upper sealing pre-tightening sleeve 3, upper sealing
Pre-tightening sleeve 3, upper preload pressure cap 2 and compressible I 3-1 of sealing ring of 4 collective effect of pretension bolt;One 6 sets of upper cover is pre- in upper sealing
The upper surface of clamper cylinder 9 is bolted on fixed 3 and by connection;Along it axially through being equipped in the seaming chuck 1
Inlet pipeline 1-2;
The lower end cap 17 includes the plug lower part 17-3 and the upper part of the plug 17-2 for going deep into copper sheathing 12, the upper part of the plug 17-2 diameter
It is greater than plug lower part 17-3 radial dimension to size, once pre-tightens inner sleeve 16 and be inserted in lower end cap 17 and the upper end from below along axial direction
Withstand the upper part of the plug 17-2, the lower upper surface for pre-tightening inner sleeve 16 is equipped with II 16-1 of a sealing ring, and the lower inner sleeve 16 that pre-tightens
Peripheral surface is fitted closely with 12 inner surface of copper sheathing;One 18 sets of lower head is bolted on the 17-3 of plug lower part and through connection
To the lower end surface of clamper cylinder 9;Along it axially through equipped with seepage flow water outlet channel 17-1, lower end cap 17 in the lower end cap 17
Dispersion shape seepage tank is equipped with the end face that core 13 contacts;What the clamper cylinder 9 was connected with upper cover 6, lower head 18
Position is all equipped with sealing structure;
1 upper surface of seaming chuck is contacted with the press member of servo-hydraulic testing machine 22, and inlet pipeline 1-2 is external to perseverance
Constant current priming device is pressed, seepage flow water outlet channel 17-1 is connected to water recycling bins by return pipe 24, and clamper cylinder 9 is coated with
One outside heating structure 23, the confining pressure oil filler point 9-3 are external to oiling device by petroleum pipeline.
Above-mentioned constant pressure and flow priming device includes constant pressure and flow twin cylinder pump 20, the water inlet of constant pressure and flow twin cylinder pump 20 with
Water container is connected, and the water outlet of constant pressure and flow twin cylinder pump 20 is connect by outlet pipe with inlet pipeline 1-2, and outlet pipe is equipped with
For monitoring II 20-1 of pressure gauge of pressure.
Oiling device is constant pressure and flow single cylinder filling pump 21;External heating structure 23 is electric heater, and on petroleum pipeline
Equipped with the pressure gauge I 25 for monitoring confining pressure.
Above-mentioned copper sheathing 12 is to be formed with mold one-piece casting, and can reuse, repeat to pour when making.
As a preferred scheme, the cylinder lower part 9-2 internal diameter of the clamper cylinder 9 is greater than clamper cylinder 9
Cylinder top 9-1 outer diameter.Lower preload housing 11 and more large end face size with more large area limit end face 11-1 can be accommodated
Positive stop lug boss 12-2 can also limited so as to install the major diameter spring for being enough to provide bigger pretightning force as needed
Greater number of preload compressed spring 14 is installed on the end face 11-1 of position, provides bigger pretensioning effect for copper sheathing 12, to meet not
Same requirement.
Preferably, the axial clamping structure include be located at 12 upper end periphery of copper sheathing spacing block set 12-1 and with its axial direction
Cooperation is located at the fixture block 10-1 for pre-tightening 10 inner ring lower part of housing.When applying pretightning force in installation process, when 12 upper surface of copper sheathing
When concordant with 9 upper surface of clamper cylinder, by upper preload housing 10 9 inner wall of clamper cylinder placed from above and 12 outer wall of copper sheathing
Between, when merging, makes the spacing block set 12-1 of 12 upper end periphery of copper sheathing and the upper fixture block 10-1 for pre-tightening 10 inner ring of housing mutually be staggered
It opens, in rotation pre-tightens housing 10 after merging fixture block 10-1 is made to block spacing block set 12-1 along axial direction and avoid copper sheathing 12 whole along axial direction
It moves down.Compressed spring 14 is pre-tightened at this time to be in compressive state and apply downward preload to the upper surface positive stop lug boss 12-2
Power, to be pre-tightened to copper sheathing 12.
Further, the lower inner ring for pre-tightening housing 11 pre-tightens housing around multiple double wedge 11-3 are distributed with instantly
11 sets when on copper sheathing 12, each double wedge 11-3 withstands the outer peripheral surface of copper sheathing 12.It is distributed multiple mono- sides of double wedge 11-3 of setting
Face can position the lower position for pre-tightening housing 11, occur the sliding relative to copper sheathing 12 radially after avoiding it from positioning;Another party
Face, when installing lower preload housing 11, double wedge 11-3 can be staggered with spacing block set 12-1 guarantees that lower preload housing 11 can be from copper sheathing
12 tops are covered from top to bottom on copper sheathing 12.
As a preferred scheme, the upper cover 6 is back to the upper surface of clamper cylinder 9 around upper sealing pre-tightening sleeve
3 are equipped with annular groove I, and an end face is equipped with 5 sets of upper envelope pressure cap of sealing ring on upper sealing pre-tightening sleeve 3 and is embedded in annular groove I, and
Upper envelope pressure cap 5 is connect by screw with upper cover 6.Upper envelope pressure cap 5 equipped with sealing ring can provide better seal, effectively keep away
Exempt from pressure oil and is oozed out between upper cover 6 and sealing pre-tightening sleeve.
As a preferred scheme, the lower head 18 is set back to the lower end surface of clamper cylinder 9 around lower end cap 17
There is annular groove II, an end face is equipped in the lower sealing compression ring 19 insertion annular groove II of sealing ring, and lower sealing compression ring 19 is logical
Screw is crossed to connect with lower head 18.Lower sealing compression ring 19 comprising sealing ring can further provide for better seal, effectively
Pressure oil is avoided to ooze out between lower head 18 and lower end cap 17.
Preferably, the sealing structure is the carbon seal ring 8 being located on 9 end face of clamper cylinder.Carbon seal ring 8 is resistance to
High temperature and pressure resistance sealing leak will not occur when loading at high temperature under high pressure.
Inlet pipeline 1-2 is 304 pre-buried stainless steel tubes.304 stainless steel tube intensity are high, can satisfy injection high pressure water pair
The requirement of the progress pressure break of core 13.
In order to not influence the compression of seaming chuck 1, the pressure head top side 1-3 is equipped with outlet inserted block 1-1, the outlet inserted block
Pipeline in 1-1 is arranged radially along seaming chuck 1 and is connected to inlet pipeline 1-2.It is convenient that inlet pipeline 1- is set in seaming chuck 1
2 without influencing press machine to the axially loaded of seaming chuck 1.
Preload compressed spring 14 is high stiffness coefficient spring, totally eight, after lower eight the preloads compressed springs 14 of room temperature are compressed
Resultant force value be copper sheathing 12 axial pre-tightening tension is provided, so that copper sheathing 12 is in elastic deformation stage;After high-temperature heating, press in advance
Contracting spring 14 continues to provide axial pre tightening force, and the resultant force value of axial pre tightening force be greater than 13 surface of core and 12 inner surface of copper sheathing it
Between stiction (stiction as from outside directly act on produced by the confining pressure of copper sheathing), so as to avoid copper sheathing 12
Occur to extend after high-temperature heating and Folding Deformation ruptures, has prevented the generation of the phenomenon of leakage.
In conjunction with specific test description liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing test method, include the following steps:
A, the cylindrical granite core 13 for preparing φ 50*100mm, in 13 upper surface centre drill counterbore of core;
B, it by lower preload housing 11 and pre-tightens compressed spring 14 and is placed in clamper cylinder 9 from below, then by 12 edge of copper sheathing
Clamper cylinder 9 is axial to be placed in clamper cylinder 9 from the bottom up, makes spacing block set 12-1 and double wedge 11-3 wrong during merging
It opens and guarantees copper sheathing 12 outside directly through the both ends up to pre-tightening compressed spring 14 respectively against lower preload in lower preload housing 11
The upper surface limit end face 11-1 and positive stop lug boss 12-2 of set 11 pre-tightens compressed spring 14 at this time and is in nature elongation state, is
Allow to pre-tighten compressed spring 14 and downward pre-tightening tension is provided, assists positioning convex platform of the mounting ring 15 by surface for one
15-1 docks mounting ring 15 will be assisted to be placed in copper sheathing 12 with the positioning groove 12-3 of the lower end surface copper sheathing positive stop lug boss 12-2
In lower part and merging clamper cylinder 9, then is withstood from below with press machine and assist the lower end surface of mounting ring 15 and press upwards to make
Assisting mounting ring 15 and copper sheathing 12, mobile compression pre-tightens compressed spring 14 axially upward, when 12 upper surface of copper sheathing and clamper cylinder
9 upper surface of body is concordant and when assisting the lower end surface of mounting ring 15 concordant with 9 lower end surface of clamper cylinder, by upper preload housing 10 from
Top is placed between 12 outer wall of 9 inner wall of clamper cylinder and copper sheathing, and when merging makes the spacing block set 12-1 of 12 upper end periphery of copper sheathing
It is mutually staggered with the upper fixture block 10-1 for pre-tightening 10 inner ring of housing, using the rotation for pre-tightening 10 upper surface of housing in tool insertion after merging
Turn location hole 10-2 and pre-tighten housing 10 on rotating, so that fixture block 10-1 is blocked spacing block set 12-1 along axial direction and avoid copper sheathing 12 whole
It is axially downward, compressed spring 14 is pre-tightened at this time to be in compressive state and the upper surface positive stop lug boss 12-2 is applied downwards
Pretightning force, to be pre-tightened to copper sheathing 12;Auxiliary mounting ring 15 is removed after completing preload process;
C, the clamper cylinder that lower preload inner sleeve 16 and lower head 18 are successively inserted on lower end cap 17 from below, and will assemble
Body 9, up and down preload housing 11 and copper sheathing 12 are mounted on lower head 18 entirely through connection bolt;
D, by core 13 out of top merging copper sheathing 12, the seaming chuck 1 that outside is cased with upper sealing pre-tightening sleeve 3 is placed in copper sheathing
12 and core 13 is pushed down, upper 2 screw-tightened of preload pressure cap is set in pressure head top 1-3, and make pretension bolt 4 and seaming chuck 1
The axial upper surface for withstanding upper sealing pre-tightening sleeve 3 again parallel across upper preload pressure cap 2 seals 3 lower end surface of pre-tightening sleeve to compress
I 3-1 of sealing ring, 6 sets of upper cover is bolted to the upper end of clamper cylinder 9 on upper sealing pre-tightening sleeve 3 and through connection
Face, in the counterbore at the one end inlet pipeline 1-2 insertion 13 upper surface center of core in seaming chuck 1, the other end is connected to constant pressure and constant
It flows on twin cylinder pump 20;Clamper cylinder 9 is integrally placed in external heating structure 23;
E, it is pushed down seaming chuck 1 with servo-hydraulic testing machine 22 and is loaded and axis pressure is provided, by confining pressure oil filler point 9-3 and constant pressure and constant
It flows single cylinder filling pump 21 to connect, be enclosed with constant pressure and flow single cylinder filling pump 21 by the intracavitary load of high temperature resistant Silicone oil injection confining pressure is certain
Pressure, axis pressure, confining pressure are alternately loaded onto test objective value;
F, after ambient stress required for reaching, external heat to test is carried out to core 13 using external heating structure 23 and is set
Determine temperature, this process keeps tracking and adjusting in time by pressure gauge to confining pressure, and thermal stress is avoided to fluctuate confining pressure;
G, after temperature and ambient stress reach test sets requirement, pass through inlet pipeline 1-2 with constant pressure and flow twin cylinder pump 20
Pressure break is carried out to sample to 13 injection pressure power water of core, water is flowed out from return pipe 24 after pressure break, and pressure is at any time during record test
Between the curve that changes;
H, clamper is dismantled after the test and carries out next group of test.
It as shown in Figure 10, is the pressure of the pressure water monitored respectively when test temperature is respectively 200 DEG C, 360 DEG C, 450 DEG C
Power versus time curve, the abrupt pressure reduction point (at black arrow) in figure indicate the hydrofracturing crack initiation pressure of core 13
Power.It can be seen that when test temperature is respectively 200 DEG C, 360 DEG C, 450 DEG C, hydrofracturing pressure be respectively 77MPa,
50MPa、42MPa。
Claims (9)
1. a kind of liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system, including clamper, the clamper include the clamping being vertically arranged
Device cylinder (9) is coaxially equipped with a copper sheathing (12) in the clamper cylinder (9), and being equipped in clamper cylinder (9) wall can be from
Confining pressure oil filler point (9-3) of the outside to the confining pressure chamber note pressure oil between clamper cylinder (9) and copper sheathing (12), a seaming chuck
(1) be coaxially inserted from above into copper sheathing (12) with clamper cylinder (9), a lower end cap (17) and clamper cylinder (9) coaxially from
Lower section is inserted into copper sheathing (12), is equipped with core (13) in the space that seaming chuck (1), lower end cap (17) are surrounded with copper sheathing (12),
It is characterized in that,
It is outer that clamper cylinder (9) top is arranged preload on one between clamper cylinder (9) inner wall and copper sheathing (12) outer wall
It covers (10), copper sheathing (12) passes through axial clamping structure cooperation with upper preload housing (10) and is connected together;The clamper cylinder
(9) lower part is arranged preload housing (11) between clamper cylinder (9) inner wall and copper sheathing (12) outer wall, and under copper sheathing (12)
End ring is equipped with positive stop lug boss (12-2) around peripheral surface, and lower preload housing (11) is towards the upper surface positive stop lug boss (12-2)
It is circumferentially distributed in limit end face (11-1) and pre-tightens compressed spring (14), pre-tighten the both ends of compressed spring (14) respectively against limit
Position upper surface end face (11-1) and positive stop lug boss (12-2);
The seaming chuck (1) includes pressure head top (1-3), pressure head ontology (1-4) and the pressure head for going deep into copper sheathing (12) from top to bottom
Lower part (1-5), pressure head lower part (1-5) radial dimension are greater than the radial dimension in the middle part of pressure head, and pre-tightening sleeve (3) are sealed on one from top
It is inserted in seaming chuck (1) and its lower end edge is axially withstood pressure head lower part (1-5), the lower end surface of upper sealing pre-tightening sleeve (3) is equipped with
One sealing ring I (3-1), and the lower outer peripheral surface of upper sealing pre-tightening sleeve (3) is fitted closely with copper sheathing (12) inner surface;One pre-tightens
Bolt (4) is axially set in the upper preload pressure cap (2) on pressure head top (1-3) parallel across screw-tightened with seaming chuck (1) and pushes up
Live in seal the upper surface of pre-tightening sleeve (3);One upper cover (6) is covered on upper sealing pre-tightening sleeve (3) and is bolted by connection
To the upper surface of clamper cylinder (9), along it axially through being equipped with inlet pipeline (1-2) in the seaming chuck (1);
The lower end cap (17) includes plug lower part (17-3) and the upper part of the plug (17-2) for going deep into copper sheathing (12), the upper part of the plug
(17-2) radial dimension is greater than plug lower part (17-3) radial dimension, once pre-tightens inner sleeve (16) and is inserted in lower end cap (17) from below
And the upper end is withstood the upper part of the plug (17-2) along axial direction, the lower upper surface for pre-tightening inner sleeve (16) is equipped with II (16- of a sealing ring
1), and the lower peripheral surface for pre-tightening inner sleeve (16) is fitted closely with copper sheathing (12) inner surface;One lower head (18) covers under plug
The lower end surface of clamper cylinder (9) is bolted in portion (17-3) and by connection;Along its axial direction in the lower end cap (17)
Perforation is equipped with seepage flow water outlet channel (17-1), the portion that the clamper cylinder (9) is connected with upper cover (6), lower head (18)
Position is all equipped with sealing structure;
Seaming chuck (1) upper surface is contacted with the press member of a servo-hydraulic testing machine (22), the inlet pipeline (1-2)
It is external to constant pressure and flow priming device, seepage flow water outlet channel (17-1) is connected to water recycling bins, clamper by return pipe (24)
Cylinder (9) is coated with an outside heating structure (23), and the confining pressure oil filler point (9-3) is external to oiling by petroleum pipeline and fills
It sets.
2. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the constant pressure and flow
Priming device includes constant pressure and flow twin cylinder pump (20), and the water inlet of constant pressure and flow twin cylinder pump (20) is connected with water container, constant pressure and constant
The water outlet of stream twin cylinder pump (20) is connect by outlet pipe with inlet pipeline (1-2), and outlet pipe is equipped with for monitoring pressure
Pressure gauge II (20-1).
3. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the oiling device is
Constant pressure and flow single cylinder filling pump (21);External heating structure (23) is electric heater, and petroleum pipeline is equipped with and encloses for monitoring
The pressure gauge I (25) of pressure.
4. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the clamper cylinder
(9) cylinder lower part (9-2) internal diameter is greater than cylinder top (9-1) outer diameter of clamper cylinder (9).
5. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the axial clamping knot
Structure include be located at copper sheathing (12) upper end periphery spacing block set (12-1) He Yuqi axially engage be located at pre-tighten housing (10) in
Enclose the fixture block (10-1) of lower part.
6. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the lower preload housing
(11) inner ring pre-tightens housing (11) instantly and covers when on copper sheathing (12) around multiple double wedges (11-3) is distributed with, each double wedge
(11-3) withstands the outer peripheral surface of copper sheathing (12).
7. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the upper cover (6)
It is equipped with annular groove I around upper sealing pre-tightening sleeve (3) back to the upper surface of clamper cylinder (9), an end face is equipped with the upper of sealing ring
Envelope pressure cap (5) is covered on upper sealing pre-tightening sleeve (3) and is embedded in annular groove I, and upper envelope pressure cap (5) passes through screw and upper cover
(6) it connects.
8. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that the lower head (18)
It is equipped with annular groove II around lower end cap (17) back to the lower end surface of clamper cylinder (9), an end face is equipped with the lower sealing of sealing ring
Compression ring (19) is embedded in annular groove II, and lower sealing compression ring (19) is connect by screw with lower head (18).
9. liquid-leakage preventing high temperature and pressure hydraulic pressure fracturing system according to claim 1, which is characterized in that pre-tighten compressed spring
(14) there are eight.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111411930A (en) * | 2020-03-26 | 2020-07-14 | 中国石油大学(北京) | Visual dynamic filtration and drainage simulation device and simulation method for tight gas reservoir fracturing fluid |
CN109870350B (en) * | 2019-03-29 | 2023-10-27 | 中国矿业大学 | Liquid leakage prevention high-temperature high-pressure hydraulic fracturing system and test method |
-
2019
- 2019-03-29 CN CN201920428119.7U patent/CN209640100U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109870350B (en) * | 2019-03-29 | 2023-10-27 | 中国矿业大学 | Liquid leakage prevention high-temperature high-pressure hydraulic fracturing system and test method |
CN111411930A (en) * | 2020-03-26 | 2020-07-14 | 中国石油大学(北京) | Visual dynamic filtration and drainage simulation device and simulation method for tight gas reservoir fracturing fluid |
CN111411930B (en) * | 2020-03-26 | 2020-10-16 | 中国石油大学(北京) | Visual dynamic filtration and drainage simulation device and simulation method for tight gas reservoir fracturing fluid |
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