RU2770639C1 - Installation for testing the influence of the heat of hydration of cement or drilling mud on the stability of natural gas hydrate - Google Patents

Abstract

FIELD: testing devices.SUBSTANCE: present invention relates to an apparatus for testing the effect of the heat of hydration of a cement or drilling mud on the stability of natural gas hydrate, which comprises a gas source 1; pressure control valve 2; device 3 for measuring the mass flow of gas; pressure gauge 4; thermostatic tank 6; switching valve 7 water source; made with the possibility of observation of the reaction boiler 8; control panel 13; computing device 16; heating jacket 23; pressure sensor 24; temperature sensor 25; at the same time, the reaction boiler, made with the possibility of observation, is connected in series with a pressure gauge, a gas mass flow measurement device, a pressure control valve and a gas source, and is also connected to a thermostatic tank by means of a water source switching valve. The reaction boiler is surrounded on the outside by a heating jacket, on which several temperature sensors and pressure sensors are respectively located on both sides. When used in the process of cementing a well, a cylinder with a cement slurry is fixed in the center of the boiler body, while a cement slurry is placed in the cylinder with a solution; when used in a well drilling process, a drilling fluid circulation line is located in the center of the boiler body, wherein the drilling fluid circulation line is connected to the drilling fluid pumping line.EFFECT: present invention is characterized by a simple and fast testing process and can be used in studies of the effects of heat released during hydration of cement slurry and drilling fluid on the stability of natural gas hydrate.4 cl, 3 dwg

Description

Technical field

[0001] The present invention relates to apparatus for measuring and monitoring the stability of natural gas hydrate under certain conditions, in particular it relates to apparatus for testing the effect of the heat of hydration of a cement slurry/drilling mud on the stability of natural gas hydrate.

Background of the invention

[0002] In the process of transporting natural gas, a problem can often arise due to the fact that in certain places of sections of the mine shaft and pipeline, due to the ingress of liquid into the natural gas, hydrate is formed, which clogs the pipeline, or due to large drops in the natural gas pipeline. gas accumulates in special areas, which leads to blockage of the pipeline.

[0003] In the field of oil production, great attention is always paid to the question of whether the heat of hydration of a cement slurry for cementing a well will destroy the stability of the natural gas hydrate layer when performing well cementing, in particular deep water well cementing. If the stability of the natural gas hydrate in the hydrate layer is disturbed, it will cause the collapse of the reservoir in the production area and the cycle of solidification and decomposition of the natural gas hydrate after it enters the cement for well cementing, due to which a number of mechanical properties of the resulting cement ring will not be meet standards. Therefore, the problem of the effect of the heat of hydration of a cement system for well cementing or drilling fluid on the stability of natural gas hydrate always remains relevant for specialists performing deep-water well cementing.

[0004] Today, pressure and temperature modeling through digital simulation technologies is increasingly applied to the conditions for ensuring the stability of natural gas hydrate, but there will always be certain errors in relation to the established parameters and the environment during construction work on the site, so the results from the very beginning cannot ideal for the construction site; formulas obtained by numerical approximation are suitable for certain conditions, and a change in the place of development or other conditions casts doubt on the applicability of such formulas.

[0005] Modeling the formation and decomposition of natural gas hydrate, carried out in the laboratory, is characterized by the following disadvantages: the inability to directly observe the situation in the reaction boiler; the lack of a certain accuracy in determining and regulating pressure and temperature; the presence of contact between gas and liquid only at the interface between gas and liquid, while the limited contact area has a certain effect on the formation of natural gas hydrate.

[0006] Today, research and development of test facilities capable of observing, verifying, and analyzing the effect on natural gas hydrate stability of the heat generated by hydration of a cement slurry or drilling fluid is of paramount importance.

The essence of the invention

[0007] It is an object of the present invention to provide an apparatus for testing the effect of the heat of hydration of cement slurry/drilling mud on the stability of natural gas hydrate, characterized by sound fundamentals, rational design, simple and fast testing process, easy flushing capability, and at the same time by means of the ability to observe the window in the reaction boiler, you can directly observe the formation and decomposition of natural gas hydrate under conditions of different temperatures and pressures, test and investigate cement slurry systems for well cementing, as well as patterns of influence of the amount of heat released during drilling fluid hydration on the stability of natural gas hydrate gas.

[0008] To solve the above technical problem, the present invention uses the following technical solution.

[0009] The apparatus for testing the influence of the heat of hydration of cement slurry/drilling fluid on the stability of natural gas hydrate is mainly composed of a high-pressure reaction boiler equipped with an observation window, a drilling fluid injection and circulation system, a cement slurry element, a thermostatic tank, a control system and temperature control, pressure regulation and control system, magnetic stirring device, drilling fluid element, data acquisition units and data processing units.

[0010] Said high pressure reaction boiler is mounted on a base with a magnetic stirrer at the bottom; the reaction kettle is provided with an observable viewing window, which is made transparent, which, in combination with a cold light source, makes it possible to clearly observe the formation and decomposition of hydrate in the reaction kettle.

[0011] The specified temperature control system includes a thermostatic tank, temperature sensors, and a heating jacket located outside the reaction boiler on both sides; by means of a thermostatic tank, the temperature of the injected water source is regulated; by means of a heating jacket, a secondary regulation of the actual temperature of the water source entering the inside of the reaction boiler is performed; temperature sensors extend inside the reaction kettle, collect real-time temperature data inside the reaction kettle, and transmit the data to the control panel and computing device.

[0012] Said mud pumping system is mainly composed of a mud pump, a constant temperature mud storage device, and a circulation pump; mud pump provides mixing and pumping of drilling mud; the pumped mud will be stored in the constant temperature mud storage device, and then the mud will be circulated through the circulation pump.

[0013] The drilling fluid circulation system is mainly designed to study the effect of heat released during drilling fluid hydration, while the channel passes through the reaction boiler with natural gas hydrate, and the contact between the casing and the formation during drilling of the well can be better modeled, so that determine whether or not the amount of heat of hydration of the drilling fluid can affect the stability of the hydrate. The connecting pipeline used in the mud circulation system inside the reaction kettle is made of copper material; the circulation pipeline, attached to the reaction boiler from the outside, is made of a heat-insulating material and is covered with a layer of rubber coating on the outside.

[0014] The slurry element is a slurry cylinder, comprising a slurry cylinder and a cylinder cover; the resulting cement slurry is loaded into the slurry cylinder and quickly enters the specified location inside the reaction kettle, and then the effect of the cement slurry on the formation and decomposition of natural gas hydrate is determined.

[0015] A source of water is supplied to the reaction kettle through an outside thermostatic tank, and the stirrer for the reaction kettle is a bottom-applied magnetic stirrer and can perform sufficient stirring of the mixture inside the reaction kettle. The temperature can be controlled by a thermostatic tank, and when controlled, the temperature can reach -15-190°C (Note: the water source used at -15-5°C is an anti-freeze liquid mixture in which ethylene glycol is added to the water, for example 40 % ethylene glycol + 60% soft water, the water source used at 5-90°C is deionized water, at 90-190°C, heat-conducting oil is used, and is mainly applied to test the heat of hydration of high-temperature cement slurry. liquids are performed based on the test temperature); by means of a control panel or a computer, manually set the rate of temperature increase and the target temperature; by means of the reaction boiler side heating jacket, secondary inlet temperature control is performed (Note: the heating jacket heating mechanism is based on liquid heating, and the liquid used in the case when the test temperature is -15-5°C is a non-freezing liquid, which composed of 40% ethylene glycol + 60% soft water; liquid used when this temperature is 5-90°C is deionized water; liquid used when this temperature is 90-190°C , is a thermally conductive oil); the temperature provided in the reaction kettle is the set temperature; and information about the temperature in the reaction boiler through temperature sensors is transmitted to the control panel in real time. By means of the pressure regulating valve, the pressure can be regulated; by means of a sulfur-resistant manometer, real-time pressure control is carried out; By means of a gas flow measurement device, the amount of gas pumped can be measured and recorded. Temperature sensors and pressure sensors installed at the same height on both sides make it easy to accurately monitor temperature and pressure data. Inject the gas source and the liquid source required for testing and verification; provide the temperature and pressure required for testing and verification; by means of an observable window of the reaction vessel, the formation and decomposition of natural gas hydrate under conditions of such temperature and pressure is evaluated; using a drilling fluid that is pumped into the reaction kettle, or oil well cement that is loaded into a cylinder of cement slurry, investigate the effect of heat released during the hydration of the drilling fluid or oil well cement on the stability of natural gas hydrate; By adding heat of hydration inhibitors to oil and gas well cement slurry, the effect of heat of hydration inhibitors is evaluated.

[0016] Compared with analogues known from the prior art, the present invention is characterized by the following beneficial effects:

(1) test results are visual, can directly observe the decomposition and formation of natural gas hydrate in the reaction kettle;

(2) a temperature in the range of -15-190°C can meet the temperature requirements of low temperature cementing conditions and high temperature hydration heat testing conditions;

(3) the design of the drilling fluid pipeline and the cement slurry cylinder allows modeling the interaction between the casing string and the natural gas hydrate layer during mud construction;

(4) good heat tightness and accurate test results;

(5) The proposed setup may take into account the heat released during hydration of the drilling fluid and cementing system during well cementing and the stability of natural gas hydrate to investigate the heat released during cement hydration for oil and gas wells;

(6) Thermodynamic inhibitors, kinetic inhibitors, anti-coagulants and products in which they are combined can also be added to the solution, and the effectiveness of the inhibitors can be effectively and clearly evaluated.

[0017] The present invention can be used in studies of a number of engineering problems related to the non-compliance of the quality of well cementing with standards, which is caused by the decomposition of natural gas hydrate during deep water well drilling, subsidence, etc., and, in particular, can be used for monitoring, analysis and investigating whether the heat released during hydration during the movement of the cement slurry system for cementing the well and drilling fluid can lead to the decomposition of natural gas hydrate.

Description of attached graphics

[0018] FIG. 1 is a schematic representation of the setup for testing the effect of the heat of hydration of a cement slurry/drilling fluid on the stability of natural gas hydrate.

[0019] FIG. 2 is a schematic representation of the design of the reaction boiler (with element with cement slurry).

[0020] FIG. 3 is a schematic representation of the design of the reaction boiler (with mud element).

[0021] In the figures: 1 - gas source; 2 - pressure control valve; 3 - device for measuring the mass flow of gas; 4 - sulfur-resistant manometer; 5 - high pressure safety valve; 6 - thermostatic tank; 7 - switching fittings of the water source; 8 - made with the possibility of observation of the reaction boiler; 9 - magnetic stirring device; 10 - tank for accumulation of drilling fluid with a circulation pump; 11 - fittings for pumping drilling mud; 12 - drilling mud pump; 13 - control panel; 14 - temperature data processing unit; 15 - pressure data processing unit; 16 - computing device; 17, 30 - fixing bolt; 18, 31 - reaction boiler bolt; 19, 28 - heat-insulating plate; 20 - cylinder cover with cement mortar; 21 - top cover of the reaction boiler; 22 - bottom cover of the reaction boiler; 23 - heating jacket; 24 - pressure sensor; 25 - temperature sensor; 26 - cylinder with cement mortar; 27 - upper bottom of the reaction boiler; 29 - lower bottom of the reaction boiler; 32 - circulation pipeline for drilling fluid; 33 - connecting bolt; 34 - pipeline for pumping drilling fluid.

Specific Implementation Methods

[0022] To make it easier for those skilled in the art to understand the present invention, the present invention is further described below with reference to the accompanying drawings. However, it should be understood that the scope of the present invention is not limited to specific methods of implementation, and changes proposed by experts in this field of technology are included in the scope of protection of the present invention, if they are within its essence and scope, defined and established on the basis of the attached claims inventions.

[0023] With reference to FIG. one.

[0024] An apparatus for testing the effect of heat of hydration of cement slurry/drilling mud on the stability of natural gas hydrate comprises a gas source 1; pressure control valve 2; device 3 for measuring the mass flow of gas; pressure gauge 4; thermostatic tank 6; switching valve 7 water source; made with the possibility of observation of the reaction boiler 8; device 9 magnetic mixing; control panel 13; a temperature data processing unit 14; a pressure data processing unit 15; computing device 16; heating jacket 23; pressure sensors 24; and temperature sensors 25.

[0025] Said observable reaction kettle 8 is mounted on a base with a magnetic stirring device 9 and provided with an observation window, the reaction kettle is connected in series with a pressure gauge 4, a gas mass flow measurement device 3, a pressure control valve 2, and a gas source 1 , and also by means of switching fittings 7 of the water source is connected to the thermostatic tank 6; the reaction boiler is surrounded on the outside by a heating jacket 23, on which several temperature sensors 25 and pressure sensors 24 are respectively located on both sides; the temperature sensors and the pressure sensors are connected to the temperature data processing unit 14 and the pressure data processing unit 15, respectively; the temperature data processing unit and the pressure data processing unit are respectively connected to the control panel 13 and the computing device 16; the specified made with the possibility of observation of the reaction boiler contains the boiler cover and the bottom of the boiler; the boiler cover includes a boiler top cover 21, a boiler bottom cover 22, and a heat-insulating plate 19; the bottom of the boiler contains the upper bottom 27 of the boiler, the lower bottom 29 of the boiler and the heat-insulating plate 28; the top cover 21 of the boiler and the bottom bottom 29 of the boiler, respectively, are connected to the boiler body by means of fixing bolts 17 and 30.

[0026] When using this installation in the process of cementing a well (see Fig. 2), a cylinder 26 with cement mortar is fixed in the center of the body of the reaction boiler by means of bolts 18 and 31 of the reaction boiler, as well as the bottom cover 22 of the reaction boiler and the upper bottom 27 of the reaction boiler. , wherein the solution cylinder comprises a cylinder cover 20; cement mortar is placed in a cylinder with mortar.

[0027] When using this installation in the process of drilling a well (see Fig. 3), in the center of the body of the reaction boiler, a circulation pipeline 32 for drilling fluid is provided; the circulation pipeline for drilling fluid through the connecting bolts 33 is made in communication with the pipeline 34 for pumping drilling fluid; the drilling fluid injection pipeline is connected in series with the drilling fluid storage tank 10 with a circulation pump, a drilling fluid injection fitting 11 and a drilling fluid pump 12.

[0028] The cylindrical wall of said cement slurry cylinder is made of copper material; the size of said mud circulation pipe is equal to the size of the cement slurry cylinder, and it is also made of copper material.

[0029] These temperature sensors are used in combination with pressure sensors and are provided with them in pairs at the same height to accurately collect data on temperature and pressure inside the reaction boiler. The temperature data acquisition unit and the pressure data acquisition unit are connected to the control panel, and they are also connected to the temperature data processing unit and the pressure data processing unit, and then, by means of a computing device, data is collected and summarized, and image analysis and processing is performed.

[0030] The effect of the heat of hydration of cement slurry/drilling fluid on the stability of natural gas hydrate is determined by means of the above apparatus, the specific process being as follows:

The control panel 13 sets the reaction temperature and pressure; set the temperature in the thermostatic tank 6; during the temperature increase period of the thermostatic tank, it is checked whether the temperature data acquisition unit 25 and the pressure data acquisition unit 24 are correctly connected to the control panel; installing the upper bottom 27 of the reaction kettle, the bottom heat-insulating plate 28 and the bottom bottom 29 of the kettle, which are fixed and stabilized by fixing bolts 30; to fix the cylinder 26 with cement mortar, the bolt 31 of the bottom cover is used. A cylinder with cement mortar is installed and fixed in a predetermined position at the bottom of the boiler; then similarly install the bottom cover 22 of the reaction kettle, the upper heat-insulating plate 19 and the top cover 21 of the reaction kettle; they are fixed by means of fixing bolts 17 and bolt 18 of the reaction boiler.

[0031] Then, the water source changeover valve 7 is opened to allow the water source to be supplied. Close the switching valve of the water source; ensure that the high pressure safety valve 5 is closed; open the switching valve of the gas source 1 to ensure gas supply; close the switching valve of the gas source. Turn on the "automatic mode" of the control panel; by means of the heating jacket 23 of the reaction boiler and the pressure control valve 2, the pressure and temperature are controlled; include a device 9 magnetic stirring. By means of an observation window, the inside of the reaction vessel is monitored; after the formation of natural gas hydrate, the boiler cover and the heat-insulating plate are opened; open the lid 20 of the slurry cylinder, and quickly pour the cement slurry prepared according to the API standard into the slurry cylinder. The computing device 16 is turned on for data collection.

[0032] After completing the grout test, first turn off the automatic mode of the control panel. Then, the high-pressure safety valve 5 is opened, the high-pressure gas inside the reaction kettle is released, and the magnetic stirring device is turned off. The cylinder with the solution is removed and washed.

[0033] Shown in FIG. 3, the mud pumping conduit 34 is a conduit that is connected to the mud circulating pump storage tank 10 as shown in FIG. 1, while pumping occurs from the lower side of the reaction boiler, and pumping occurs from the upper side. Before starting the mud test, firstly, the circulation mud line 32 is connected to the mud pump line 34 by means of the connecting bolts 33 and checked for leaks. After the formation of hydrate, the resulting drilling fluid is pumped by a circulation pump, then data collection is started. After completion of the test, open the high pressure relief valve and turn off the magnetic stirrer. The drilling fluid circulation line is removed and flushed.

Claims (4)

1. Installation for testing the effect of heat of hydration of cement or drilling mud on the stability of natural gas hydrate, containing a gas source (1); pressure control valve (2); device (3) measuring the mass flow of gas; pressure gauge (4); thermostatic tank (6); switching fitting (7) of the water source; made with the possibility of observation of the reaction boiler (8); device (9) magnetic mixing; control panel (13); block (14) processing data on temperature; a pressure data processing unit (15); computing device (16); heating jacket (23); pressure sensors (24); and temperature sensors (25); characterized in that said reaction boiler (8) made with the possibility of observation is mounted on a base with a magnetic stirring device (9) and provided with an observation window, while the reaction boiler is connected in series with a pressure gauge (4), a gas mass flow measurement device (3) , pressure control valve (2) and gas source (1), as well as by means of switching fittings (7) of the water source is connected to the thermostatic tank (6); the reaction boiler is surrounded on the outside by a heating jacket (23), on which several temperature sensors (25) and pressure sensors (24) are respectively located on both sides; temperature sensors and pressure sensors are connected respectively to the temperature data processing unit (14) and the pressure data processing unit (15); the temperature data processing unit and the pressure data processing unit are respectively connected to the control panel (13) and the computing device (16); the specified made with the possibility of observation of the reaction boiler contains the boiler cover and the bottom of the boiler; the boiler cover contains the top cover (21) of the boiler, the bottom cover (22) of the boiler and the heat-insulating plate (19); the bottom of the boiler contains the upper bottom (27) of the boiler, the lower bottom (29) of the boiler and the heat-insulating plate (28); the top cover of the boiler and the bottom bottom of the boiler are respectively connected to the boiler body by fixing bolts. 2. Installation for testing the effect of the heat of hydration of cement or drilling mud on the stability of natural gas hydrate according to claim 1, characterized in that when using this installation in the process of cementing a well in the center of the reaction boiler body by means of bolts (18, 31) of the reaction boiler, and also, the bottom cover (22) of the reaction boiler and the upper bottom (27) of the reaction boiler are fixed with a cylinder (26) with cement mortar, while the cylinder with the solution contains a cover (20) of the cylinder; cement mortar is placed in a cylinder with mortar. 3. Installation for testing the effect of the heat of hydration of cement or drilling mud on the stability of natural gas hydrate according to claim 1, characterized in that when using this installation in the process of drilling a well, a circulation pipeline (32) for drilling mud is provided in the center of the body of the reaction boiler; the circulation pipeline for the drilling fluid is connected by means of connecting bolts (33) to the pipeline (34) for pumping the drilling fluid; pipeline for pumping drilling fluid is connected in series with the tank (10) for the accumulation of drilling fluid with a circulation pump; fittings (11) for pumping drilling fluid; and pump (12) for drilling fluid. 4. Installation for testing the effect of heat of hydration of cement or drilling mud on the stability of natural gas hydrate according to claim 2 or 3, characterized in that the cylindrical wall of the specified cylinder with cement mortar is made of copper material; the size of said mud circulation pipe is equal to the size of the cement slurry cylinder, and it is also made of copper material.

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