CN203214026U - Experimental simulation device for CO2/N2 displacement exploitation of natural gas hydrate in cryolithozone - Google Patents

Abstract

The utility model discloses an experimental simulation device for the CO2/N2 displacement exploitation of natural gas hydrate in a cryolithozone. The device consists of a hydrate reaction model unit, a gas supply unit, a liquid supply unit, an ambient pressure control unit, an environment control unit, a vacuum treatment unit, a gas detection unit, a gas and liquid separation unit, an information acquisition and processing unit and an auxiliary unit. According to the device, the external environment of the natural gas hydrate can be actually simulated for a CO2/N2 displacement exploitation experiment in the natural gas hydrate; and in addition, the exploitation experiment can also be made by a heat injection method and a depressurization method, and a guidance can be provided for the exploitation of the natural gas hydrate.

Description

A kind of CO 2/ N 2Replacement exploitation permafrost region gas hydrates experimental simulation device

Technical field

The utility model relates to a kind of experimental facilities, relates in particular to a kind of CO ₂/ N ₂Replacement exploitation permafrost region gas hydrates experimental simulation device.

Background technology

Gas hydrates refer to a kind of cage modle crystalline solid that natural gas and water generate under specified temp and pressure, like the ice and snow shape, because it can be lighted, be " combustible ice " so be commonly called as.The research initial stage mainly is in order to suppress the generation of hydrate, but along with the energy shortage aggravation, gas hydrates have progressively caused domestic and international scientist's concern, and has carried out relevant exploration, exploitation and experimental study.As a kind of high density energy, it distributes extensively, reserves are big and it is shallow to bury, and become desirable alternative energy source of 21 century.

Gas hydrates mainly are distributed in ocean, lake and permafrost region, characteristics based on hydrate, it is different with the exploitation of conventional energy resource, when the temperature and pressure condition changes, gas hydrates may undergo phase transition, become gas from solid, this exploration and development to gas hydrates has brought a no small difficult problem.At present, the exploitation method of gas hydrates mainly contains the integrated application of voltage drop method, thermal excitation, chemical-agent technique and these three kinds of methods, its basic ideas are the artificial temperature and pressure equilibrium conditionss that gas hydrates exist of breaking, gas hydrates are decomposed, then natural gas is adopted to ground, but these schemes can might cause problems such as submarine landslide or sedimentation; Recently the technology based on the carbon dioxide replacement exploitation of gas hydrate of principle,displacement more and more causes people's attention, by carbon dioxide the gas replacement in the gas hydrates is come out, obtain carbon dioxide hydrate and natural gas, so both can realize the exploitation of gas hydrates, can realize again that carbon dioxide is underground and seal up for safekeeping, reduce greenhouse effect.

Because it is comparatively complicated that gas hydrates carry out field experiment research, the experimental study of at present relevant exploitation of gas hydrates is mainly the laboratory experiment simulation, and it is in the majority with simulation ocean porous media hydrate, the professional simulation laboratory that is primarily aimed at permafrost region exploitation of gas hydrates experimental study is less at present, and the laboratory that stresses to carry out the research of carbon dioxide replacement experimental simulation is also less.

The utility model content

The purpose of this utility model is to provide a kind of CO ₂/ N ₂Replacement exploitation permafrost region gas hydrates experimental simulation device, this experimental simulation device can carry out CO ₂/ N ₂Replacement exploitation permafrost region exploitation of gas hydrates mechanism and production performance research, the experimental study that can also carry out heat injection and step-down exploitation in addition is optimized and estimates at various exploitation methods.

The utility model is made up of with processing unit and auxiliary unit hydrate reaction under high pressure model unit, air supply unit, liquid-supply unit, confined pressure control module, environment control unit, vacuum treatment unit, gas detection cell, gas-liquid separation unit, information gathering; Described hydrate reaction model unit comprises the checkout gear on reaction kettle body and the kettle, described reaction kettle body is the clamper structure, described checkout gear comprises temperature pick up, pressure sensor and Vltrasonic device, described hydrate reaction under high pressure model unit places the insulating box of environment control unit, which is provided with gas, liquid is imported and exported and the sensor probe interface, outlet links to each other with the described gas-liquid entrance of clamper air supply unit with liquid-supply unit, the back pressure control device of environment control unit and the gas of clamper, the liquid outlet is communicated with, and link to each other with gas-liquid separation unit, described confined pressure control module links to each other with the confined pressure control liquid access of clamper, described vacuum treatment unit interface links to each other with the gas inlet and outlet of hydrate reaction under high pressure model unit, described information gathering and processing unit are handled the information of gathering, and described auxiliary unit comprises rock core treating apparatus and safety valve.

Hydrate reaction under high pressure model unit is used for synthesize and exploitation of gas hydrate and by the experimentize detection of process of sensor; Air supply unit is used for supplying with to hydrate reaction under high pressure model unit the mist of natural gas, carbon dioxide and nitrogen and carbon dioxide, and can control the flow of input gas; Liquid-supply unit is used for supplying with working solution (water or liquid carbon dioxide) to hydrate reaction under high pressure model unit, and can carry out preheating to water, is used for thermal recovery hydrate experimental study; The confined pressure control module is used for the control gum cover, makes it be attached to rock surface closely; Environment control unit is used for environment temperature and the pressure of control hydrate reaction under high pressure model unit, creates the temperature and pressure condition that generates gas hydrates; Vacuum treatment unit is for the vacuum that controls environment, the interference of deaeration; Gas detection cell is as on the gas liquid outlet pipeline, for detection of gas componant, and the replacement ratio when analyzing the carbon dioxide replacement hydrate; Gas-liquid separation unit is for separating of the gas of exploiting out and liquid, and measures respectively, in order to carry out the evaluation of exploitation effect; Information gathering and processing unit obtain corresponding curve, so that each data is carried out overall merit for the treatment of the data of measuring; Handle and punching is handled by the crack for rock core is carried out for the rock core treating apparatus of auxiliary unit, so that the exploitation situation under the simulation fissuted medium and transferring of popping one's head in.

The beneficial effects of the utility model:

The utility model can be simulated the gas hydrates external environment condition truly, carries out CO ₂/ N ₂Replacement exploitation of gas hydrate experiment also can be carried out heat injection method and voltage drop method exploitation experiment in addition, for the exploitation of gas hydrates provides guidance.

Description of drawings

Fig. 1 is structured flowchart of the present utility model.

Fig. 2 is the cross-sectional view of the hydrate reaction model unit of analogue means.

Fig. 3 is the probe distribution schematic diagram of the utility model hydrate reaction model unit.

Fig. 4 is the rock core processing unit schematic diagram of the utility model hydrate reaction model unit.

Fig. 5 is temp probe and the pressure probe installation site schematic diagram of the utility model hydrate reaction model unit.

Wherein: Z-rock core model, 1-hydrate reaction model unit, the 2-temp probe, the 3-pressure probe, the 4-ultrasonic probe, the 5-gum cover, 6-gum cover plug, 7-permeates blister steel, the 8-baffle plate, the 9-top board, 10-end cap, 11-reaction chamber, 12-clamper shell, 13-ring means of press seals chamber, the import of 14-ring hydraulic fluid, the outlet of 15-ring hydraulic fluid, the 16-gas feed, liquid-inlet under the 17-, the last liquid-inlet of 18-, 19-gas liquid outlet, 20-first temperature pick up, the 21-pressure sensor, 22-ultrasonic unit, 23-methane gas cylinder, 24-nitrogen gas cylinder, the 25-dioxide bottle, 26-first reducing valve, 27-second reducing valve, 28-the 3rd reducing valve, 33-the 4th reducing valve, 77-the 5th reducing valve, 82-the 6th reducing valve, 29-first stop valve, 30-second stop valve, 31-the 3rd stop valve, 37-the 4th stop valve, 38-the 5th stop valve, 39-the 6th stop valve, 42-the 7th stop valve, 43-the 8th stop valve, 44-the 9th stop valve, 49-the tenth stop valve, 50-the 11 stop valve, 51-the 12 stop valve, 52-the 13 stop valve, 53-the 14 stop valve, 54-the 15 stop valve, 55-the 16 stop valve, 61-the 17 stop valve, 62-the 18 stop valve, 63-the 19 stop valve, 64-the 20 stop valve, 72-the 21 stop valve, 75-the 22 stop valve, 79-the 23 stop valve, 80-the 23 stop valve, 32-booster pump, 34-first flow meter, 40 second flow meters, 41-the 3rd flow meter, 68-the 4th flow meter, 86-the 5th flow meter, 35-first one way valve, 58-second one way valve, 69-the 3rd one way valve, 36-first pipe pressure sensor, 48-second pipe pressure sensor, 60-the 3rd pipe pressure sensor, 71-the 4th pipe pressure sensor, 74-the 5th pipe pressure sensor, the 43-buffer container, 45-first electronic balance, 89-second electronic balance, 46-first reservoir, 88-second reservoir, 47-first constant-flux pump, 67-second constant-flux pump, 56-intermediate receptacle 56,57-preheater, the 59-Tube Temperature Sensor, 65-co 2 liquefaction device, 66-surge tank, 70-high-pressure plunger pump, 73-Tempeerature-constant air bath cabinet, the 76-back-pressure valve, 78-back pressure gas cylinder, 81-vacuum pump, 82-the 6th reducing valve, the online gas chromatograph of 83-, 84-gas-liquid separator, 85-drying box, the 87-gasholder, 90-collection of simulant signal module, 91-central processing unit, 92-printer, the 93-safety valve, the 94-guide rail, 95-electric drill, 96-support.

The specific embodiment

See also Fig. 1 and shown in Figure 4, the utility model is made up of with processing unit H and auxiliary unit K hydrate reaction under high pressure model unit 1, air supply unit A, liquid-supply unit B, confined pressure control module C, environment control unit D, vacuum treatment unit E, gas detection cell F, gas-liquid separation unit G, information gathering; Described hydrate reaction model unit 1 comprises the checkout gear on reaction kettle body and the kettle, described reaction kettle body is the clamper structure, described checkout gear comprises temperature pick up, pressure sensor and Vltrasonic device, described hydrate reaction under high pressure model unit 1 places the insulating box of environment control unit D, which is provided with gas, liquid is imported and exported and the sensor probe interface, outlet links to each other with the described gas-liquid entrance of clamper air supply unit A with liquid-supply unit B, the back pressure control device of environment control unit D and the gas of clamper, the liquid outlet is communicated with, and link to each other with gas-liquid separation unit G, described confined pressure control module C links to each other with the confined pressure control liquid access of clamper, described vacuum treatment unit E interface links to each other with the gas inlet and outlet of hydrate reaction under high pressure model unit 1, described information gathering and processing unit H handle the information of gathering, and described auxiliary unit K comprises rock core treating apparatus and safety valve.

Hydrate reaction under high pressure model unit 1 is used for synthesize and exploitation of gas hydrate and by the experimentize detection of process of sensor; Air supply unit A is used for supplying with the mist of natural gas, carbon dioxide and nitrogen and carbon dioxide to hydrate reaction under high pressure model unit 1, and can control the flow of input gas; Liquid-supply unit B is used for supplying with working solution (water or liquid carbon dioxide) to hydrate reaction under high pressure model unit 1, and can carry out preheating to water, is used for thermal recovery hydrate experimental study; Confined pressure control module C is used for the control gum cover, makes it be attached to rock surface closely; Environment control unit D is used for environment temperature and the pressure of control hydrate reaction under high pressure model unit 1, creates the temperature and pressure condition that generates gas hydrates; Vacuum treatment unit E is for the vacuum that controls environment, the interference of deaeration; Gas detection cell F is as on the gas liquid outlet pipeline, for detection of gas componant, and the replacement ratio when analyzing the carbon dioxide replacement hydrate; Gas-liquid separation unit G is for separating of the gas of exploiting out and liquid, and measures respectively, in order to carry out the evaluation of exploitation effect; Information gathering and processing unit H obtain corresponding curve, so that each data is carried out overall merit for the treatment of the data of measuring; Handle and punching is handled by the crack for rock core is carried out for the rock core treating apparatus of auxiliary unit K, so that the exploitation situation under the simulation fissuted medium and transferring of popping one's head in.

See also Fig. 2 and shown in Figure 3, described hydrate reaction model unit 1 is the clamper structure, adopt vertical placement, be placed in the Tempeerature-constant air bath cabinet 73, hydrate reaction model unit 1 is provided with gas feed 16, following liquid-inlet 17, goes up liquid-inlet 18 and gas liquid outlet 19; Air supply unit A links to each other with last liquid-inlet 18 with the gas feed 16 of hydrate reaction model unit 1, following liquid-inlet 17 with liquid-supply unit B outlet; Employing is from the lower end method of gas injection, real simulation permafrost region hydrate generting machanism; By the control of stop valve, realize from upper end fluid injection body or lower end fluid injection body; Temp probe 2, pressure probe 3 and 4 pairs of courses of reaction of ultrasonic probe detect; Rock core treating apparatus among the auxiliary unit K carries out post processing to the rock core in the hydrate reaction model unit 1.

See also shown in Figure 2ly, hydrate reaction model unit 1 is cylindrical stainless steel clamper structure, has gum cover 5, described gum cover 5 is used for wrapping rock core, gum cover all links to each other with gum cover plug 6 at two ends about in the of 5, is reaction chamber 11 with the virtual space that forms sealing, carries out the synthetic of hydrate and decomposes; There is stainless steel clamper shell 12 in gum cover 5 outsides, form a ring means of press seals chamber 13 between described clamper shell 12 and gum cover plug 6 and the gum cover 5, adopt rubber sealing between described gum cover plug 6 and the clamper shell 12, gum cover plug 6 carries out axial location by end cap 10, adopt thread connecting mode between described end cap 10 and the clamper shell 12, leave confined pressure liquid import 14 and confined pressure liquid outlet 15 on the clamper shell 12; Rock core model Z two ends up and down is respectively equipped with infiltration blister steel 7, baffle plate 8 and top board 9; Described gas feed 16, time liquid-inlet 17, last liquid-inlet 18 and gas liquid outlet 19 are separately positioned on the lower roof plate 9, and are communicated in the ring means of press seals chamber 13; Described infiltration blister steel 7 and baffle plate 8 carry out axial location by top board 9, and described top board 9 adopts thread connecting mode to be connected with end cap 10.

See also Fig. 2 and shown in Figure 5, be provided with temp probe 2 and pressure probe 3 at hydrate reaction model unit 1, also be provided with ultrasonic probe 4 at last lower baffle plate 8 places in addition; Described temp probe 2 is transferred to 1/2 radius of rock core model Z, and is connected to first temperature pick up 20; Pressure probe 3 is arranged on rock core model Z surface, presses close to gum cover 5, and is connected to pressure sensor 21; Ultrasonic probe 4 places baffle plate 8 places, presses close to rock core model Z, is connected to ultrasonic unit 22; The gas feed 16 of hydrate reaction model unit 1, down liquid-inlet 17, on liquid-inlet 18 and gas liquid outlet 19 be respectively arranged with first pipe pressure sensor 36, second pipe pressure sensor 60, the 3rd pipe pressure sensor 74, real-time monitoring pressure, also be provided with sheath temperature sensor 59 at following liquid-inlet 17, heat injection temperature monitoring when being used for thermal excitation production of water compound.

Please join shown in Figure 1, described air supply unit A comprises two cover gas circuits, one cover is a kind of gas of supply, comprise being arranged on natural gas cylinder 23, dioxide bottle 25, first reducing valve 26, the 3rd reducing valve 28, first stop valve 29 and the 3rd stop valve 31 that on the gas output tube road, also connects successively, replace with carbon dioxide for hydrate is synthetic; Another set of is mist, comprise being arranged on nitrogen gas cylinder 24, dioxide bottle 25, second stop valve 27, the 3rd stop valve 28, the 3rd flow meter 41, second flow meter 40, buffer container 43, the 6th stop valve 39, the 7th stop valve 42 and the 9th stop valve 44 that on the gas output tube road, also connects successively, this gas circuit is used for CO ₂/ N ₂The blender replacement exploitation.Two cover gas circuits merged before booster pump 32, after two cover gas circuits merge, what connect successively is to be connected with first pipe pressure sensor 36 on booster pump 32, the 4th reducing valve 33, first flow meter 34, first one way valve 35 and the 5th stop valve 38, the first one way valves 35; By the flow of first flow meter 34 control injecting gas, and pass through the pressure that first pipe pressure sensor 36 is monitored injecting gas.

Please join shown in Figure 1, described liquid-supply unit B comprises two cover liquid roads, one cover is the used working solution of supply synthesized hydrate, comprise first electronic balance 45 that is arranged on the working solution output pipe, first reservoir 46, first constant-flux pump 47, intermediate receptacle 56, the tenth stop valve 49, the 11 stop valve 50, the 12 stop valve 51, the 13 stop valve 52, the 14 stop valve 53, the 15 stop valve 54, the 16 stop valve 55, the 17 stop valve 61, the 18 stop valve 62, preheater 57, second one way valve 58, Tube Temperature Sensor 59 and the 3rd pipe pressure sensor 60, inlet is arranged in two ends up and down, and descending liquid-inlet 17 places that an emptying stop valve 63 is set, the pipeline after the preheater 57 is incubated processing; Another set of for supplying the liquid carbon dioxide that replacement exploitation is used, comprise the dioxide bottle 25, the 3rd reducing valve 28, the 20 stop valve 64, co 2 liquefaction device 65, buffer container 66, second constant-flux pump 67, the 4th flow meter 68 and the 3rd one way valve 69 that are arranged on the working solution output pipe, this cover liquid road is used for carrying out the experimental study of liquid carbon dioxide replacement exploitation of gas hydrate.

Please join shown in Figure 1ly, described confined pressure control module C comprises high-pressure plunger pump 70, the 4th pipe pressure sensor 71 and the 21 stop valve 72 that is arranged on the confined pressure control piper and connects successively, links to each other with ring hydraulic fluid import 14 then.Guarantee that by confined pressure control module C gum cover 5 closely touch rock core model Z, so the ring pressure pressure needs more than or equal to reaction simulation cavity pressure.

Please join shown in Figure 1ly, described environment control unit D includes Tempeerature-constant air bath cabinet 73 and back pressure control device, can carry out temperature to reaction model by Tempeerature-constant air bath cabinet 73 and accurately control, satisfy hydrate synthetic with decompose required environment temperature; The back pressure control device includes the 5th pipe pressure sensor 74, the 22 stop valve 75, back-pressure valve 76, the 5th reducing valve 77 and back pressure gas cylinder 78, this back pressure control device is connected gas liquid outlet 19 places, by the back pressure control device can combining air feeding pressure realization response pressure control, can also pass through back pressure control device control production pressure, carry out voltage drop method simulation mining hydrate.

Please join shown in Figure 1ly, described vacuum treatment unit E includes vacuum pump 81, the 23 stop valve 79 and the 23 stop valve 80.Carry out application of vacuum before the reaction beginning, deaeration disturbs, and at the two ends up and down of reaction model extract opening just is set, and guarantees to reach the air emptying that reaction model is imported and exported pipeline in the reaction model.

Please join shown in Figure 1ly, described gas detection cell F includes aspirating hole and the on-line gas chromatography 83 that is arranged on gas liquid outlet 19 pipelines, and aspirating hole is arranged on the 6th reducing valve 82.Through the 6th reducing valve 82, extract a certain amount of gas out from aspirating hole, utilize described on-line gas chromatography 83 to carry out constituent analysis, the analysis of replacement ratio in the time of can realizing carbon dioxide replacement exploitation by gas detection cell F.

Please join shown in Figure 1ly, described gas-liquid separation unit G includes gas-liquid separator 84, desiccant case 85, the 5th flow meter 86, gasholder 87, second fluid reservoir 88 and second electronic balance 89.Realize the gas flows metering by the 5th flow meter 86, second electronic balance 89 is realized liquid meters, and the water yield is too for a short time to be difficult to measure the metering that can also realize water by desiccant case 85 if generate.

Please join shown in Figure 1ly, described information gathering and processing unit H include collection of simulant signal module 90, central processing unit 91 and printer 92.Can the parameter that parameter measurement and control module is measured handle and store by information gathering and processing unit H, obtain corresponding data and curves and statistic, it is temperature-time graph, pressure-time curve, resistivity---time graph and replacement ratio-time graph that described data and curves includes, and described statistic includes and generates the water yield, generates gas flow and replacement ratio etc.

Please join Fig. 1 and shown in Figure 4, auxiliary unit K comprises safety valve 93 and rock core treating apparatus, wherein the rock core treating apparatus includes guide rail 94, electric drill 95 and support 96, Z is fixed on the support 96 with the rock core model, and pre-punching place is faced up, and changes corresponding guide rail 94, the security protection number of three kinds of probes of cause is different with spacing, so corresponding different guide rail 94, the locating hole place on described guide rail 94 uses electric drill 95 to punch, and this hole is used for the security sensor probe.

Claims (2)

1. CO ₂/ N ₂Replacement exploitation permafrost region gas hydrates experimental simulation device is characterized in that: be made up of with processing unit and auxiliary unit hydrate reaction under high pressure model unit, air supply unit, liquid-supply unit, confined pressure control module, environment control unit, vacuum treatment unit, gas detection cell, gas-liquid separation unit, information gathering; Described hydrate reaction model unit comprises the checkout gear on reaction kettle body and the kettle, described reaction kettle body is the clamper structure, described checkout gear comprises temperature pick up, pressure sensor and Vltrasonic device, described hydrate reaction under high pressure model unit places the insulating box of environment control unit, which is provided with gas, liquid is imported and exported and the sensor probe interface, outlet links to each other with the described gas-liquid entrance of clamper air supply unit with liquid-supply unit, the back pressure control device of environment control unit and the gas of clamper, the liquid outlet is communicated with, and link to each other with gas-liquid separation unit, described confined pressure control module links to each other with the confined pressure control liquid access of clamper, described vacuum treatment unit interface links to each other with the gas inlet and outlet of hydrate reaction under high pressure model unit, described information gathering and processing unit are handled the information of gathering, and described auxiliary unit comprises rock core treating apparatus and safety valve.

2. a kind of CO according to claim 1 ₂/ N ₂Replacement exploitation permafrost region gas hydrates experimental simulation device, it is characterized in that: described hydrate reaction model unit (1) is the clamper structure, adopt vertical placement, be placed in the Tempeerature-constant air bath cabinet (73), hydrate reaction model unit (1) is provided with gas feed (16), following liquid-inlet (17), goes up liquid-inlet (18) and gas liquid outlet (19); Air supply unit (A) links to each other with last liquid-inlet (18) with the gas feed (16) of hydrate reaction model unit (1), following liquid-inlet (17) with liquid-supply unit (B) outlet; Employing is from the lower end method of gas injection, real simulation permafrost region hydrate generting machanism; By the control of stop valve, realize from upper end fluid injection body or lower end fluid injection body; Temp probe (2), pressure probe (3) and ultrasonic probe (4) detect course of reaction; Rock core treating apparatus in the auxiliary unit (K) carries out post processing to the rock core in the hydrate reaction model unit (1);

Described hydrate reaction model unit (1) has gum cover (5), described gum cover (5) is used for wrapping rock core, gum cover (5) two ends up and down all links to each other with gum cover plug (6), is reaction chamber (11) with the virtual space that forms sealing, carries out the synthetic of hydrate and decomposes; There is clamper shell (12) in gum cover (5) outside, form a ring means of press seals chamber (13) between described clamper shell (12) and gum cover plug (6) and the gum cover (5), adopt rubber sealing between described gum cover plug (6) and the clamper shell (12), gum cover plug (6) carries out axial location by end cap (10), adopt thread connecting mode between described end cap (10) and the clamper shell (12), leave confined pressure liquid import (14) and confined pressure liquid outlet (15) on the clamper shell (12); Rock core model (Z) two ends up and down is respectively equipped with infiltration blister steel (7), baffle plate (8) and top board (9); Described gas feed (16), time liquid-inlet (17), last liquid-inlet (18) and gas liquid outlet (19) are separately positioned on the lower roof plate (9), and are communicated in the ring means of press seals chamber (13); Described infiltration blister steel (7) and baffle plate (8) carry out axial location by top board (9), and described top board (9) adopts thread connecting mode to be connected with end cap (10);

Described hydrate reaction model unit (1) is provided with temp probe (2) and pressure probe (3), locates also to be provided with ultrasonic probe (4) at last lower baffle plate (8) in addition; Described temp probe (2) is transferred to 1/2 radius of rock core model (Z), and is connected to first temperature pick up (20); Pressure probe (3) is arranged on rock core model (Z) surface, presses close to gum cover (5), and is connected to pressure sensor (21); Ultrasonic probe (4) places baffle plate (8) to locate, and presses close to rock core model (Z), is connected to ultrasonic unit (22); Gas feed (16), time liquid-inlet (17), last liquid-inlet (18) and gas liquid outlet (19) in hydrate reaction model unit (1) are respectively arranged with first pipe pressure sensor (36), second pipe pressure sensor (60), the 3rd pipe pressure sensor (74), real-time monitoring pressure, also be provided with sheath temperature sensor (59) at following liquid-inlet (17), heat injection temperature monitoring when being used for thermal excitation production of water compound.

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