RU2761000C1 - Method for preventing ice formation in a gas collecting pipeline - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to the oil and gas industry and can be used to prevent ice formation in a gas collecting pipeline. To implement the method for preventing ice formation, the gas collecting pipeline is initially blown down with gas from the wells without being released into the atmosphere. The specific liquid content in the gas is measured at the end of the gas collecting pipeline. The gas is separated during a temporary blow-down period until the specific liquid content decreases to a value determined in advance. The time of the blow-down period is fixed, the density and total volume of the separated liquid are measured, after which the gas collection pipeline is switched to the current operating mode, in which the gas flow rate in the pipeline is measured, the specific content of liquid in the gas at the beginning of the gas collection pipeline, the gas Celsius temperature at the points of entry of the inhibitor and at the first point along the gas flow from wells, in which the gas Celsius temperature has a negative value. An ice formation inhibitor is supplied and after a time calculated according to the above mathematical expression, inhibitor supply is stopped and the gas collection pipeline is blown down again with gas from the wells without being released into the atmosphere during the blowdown period fixed during the initial blowdown. The gas collecting pipeline is transferred to the current operational mode.

EFFECT: increase in the reliability of the operation of field pipelines, as well as a reduction in the consumption of an ice formation inhibitor.

5 cl, 3 dwg

Description

The invention relates to the oil and gas industry and can be used to prevent ice formation in the gas gathering pipeline.

Currently, many gas fields in Western Siberia are at a late stage of exploitation. Wells work with formation water removal. In addition, due to a decrease in reservoir pressure, the specific amount of water in natural gas and in the vapor phase increases (referred to 1000 m ^{3 of} gas, reduced to standard conditions). Due to a decrease in well production rates and, thereby, a decrease in the gas flow rate, the gas gathering system operates in the mode of accumulating liquid in the field pipelines. A gas gathering system is understood as gas gathering pipelines or field pipelines (loops and collectors) connecting well clusters or individual wells with gas treatment plants for main transport. At a late stage of field development, with a decrease in well productivity, the hydraulic flow regime in the gas gathering pipeline changes: the velocities of the liquid and gas phases begin to differ significantly (the average velocity of the liquid phase is 10-100 or more times lower than the gas velocity). This leads to the fact that, depending on the hydraulic regime and the length of the field pipeline, tens of tons of liquid (formation and condensation water together with an inhibitor of ice and hydrate formation) can accumulate in the lower sections of the route. The presence of liquid slugs leads to an increase in the pressure drop along the length of the gas gathering pipeline by 2-5% of the total pressure. At the same time, the risks of the formation of ice plugs sharply increase due to a decrease in temperature along the length of the gas gathering pipeline in the winter season, especially for field pipelines on land.

Thus, in the winter season, the temperature of the gas-liquid flow in the pipelines can drop below zero degrees Celsius, therefore, a part of the field gas gathering pipeline can be in the ice formation mode in the pipeline cavity. Some of the gas gathering pipelines (at a number of northern fields in Russia up to 15-20% of the total) in the winter season operate in the ice formation mode.

To protect gas gathering pipelines from ice formation in the winter season, a method of their operation is used, including the supply through small-diameter pipelines (methanol pipelines) to the initial section of the gas gathering pipeline (to the wellhead connection) of the calculated amount of concentrated methanol under a pressure exceeding the pressure of the transported gas. This ensures the operation of the field pipeline without ice formation (see Istomin V.A., Kvon V.G., Troynikova A.A., Nefedov P.A.Peculiarities of preventing ice and hydrate formation in gas gathering systems at the late stage of operation of Cenomanian deposits deposits of Western Siberia. Transport and storage of petroleum products and hydrocarbons, No. 2, 2016). However, the specific consumption of methanol required for this turns out to be quite high (up to 3-4 kg / 1000 m3 of gas) due to the large amount of produced formation water from wells, as well as water condensing from the gas phase. For comparison, at the initial stage of exploitation of Cenomanian deposits in Western Siberia, the average specific consumption of methanol to prevent hydrate formation in the gas gathering pipeline was only 50 g / 1000 m3 ^of gas (see A.I. Gritsenko, V.A. Istomin, A.N. Kulkov. , Suleimanov R.S. Gathering and field treatment of gas in the northern fields of Russia. - Moscow: Nedra Publishing House, 1999. - p. 295), i.e. the specific consumption of methanol increased 30-40 times.

For the considered case of a late stage of gas field exploitation, a significant drawback of the above method of gas gathering pipelines operation was revealed. There is a significant inertia of the ice inhibition process due to a long time of movement of an aqueous solution of methanol from the beginning of the gas gathering pipeline to the area protected from ice, which is due to the presence of significant liquid accumulations in the lowered sections of the pipeline, which sharply reduce the speed of the inhibitor front along the length of the gas gathering pipeline. The low rate of movement of methanol in the liquid aqueous phase leads to the fact that, for example, when the gas flow rate decreases for technological reasons, the temperature along the gas gathering pipeline decreases and, accordingly, a larger specific amount of methanol is required. Due to the inertia of the inhibition process and the presence of significant volumes of liquid in the lowered sections of the gas gathering pipelines, there are risks of the formation of an ice plug (up to the complete overlap of the pipeline section). Therefore, to ensure the reliability of inhibition, it is necessary to set a significant overrun of the inhibitor (in comparison with the theoretically minimum necessary).

The closest technical solution (prototype) to the proposed method is a method for automatic supply of an inhibitor of hydrate formation in the plumes of a gas field (RF patent No. 2637245, publ. 01.12.2017). The named method is realized with the help of a system for automatic supply of a hydrate inhibitor to gas field stubs and consists in the fact that the formation of an ice-hydrate plug is diagnosed in real time and the inhibitor is supplied directly to the section in which the formation of an ice-hydrate plug begins.

However, this method retains a fundamental disadvantage typical of the traditional method of inhibition. In the case of water inflow from the previous section of the plume in the area protected from ice, the conditions for the formation of hydrates or the formation of a plug are created due to a decrease in the concentration of the supplied methanol due to its dilution by carried out water accumulations. As a result, it remains necessary to increase the supply of methanol at the protected point of the plume to compensate for a significant part of it spent on saturating water accumulations. An increase in gas consumption, accompanied by an increase in the supply of significant volumes of liquid to the protected point, will require a corresponding increase in the supply of methanol. With a constant (calculated) supply of methanol, there are risks of the formation of ice plugs (up to a complete overlap of the pipeline cross-section).

The problem to be solved by the invention is to create a method for preventing ice formation in a gas gathering pipeline.

The technical result to which the invention is directed is to increase the reliability of the operation of field pipelines. The technical result is also a decrease in the consumption of the inhibitor of ice formation.

The specified technical result is achieved due to the fact that in the method of preventing ice formation in the gas gathering pipeline, an ice formation inhibitor is supplied to the gas gathering pipeline. At the same time, the gas gathering pipeline is initially purged with gas from the side of the wells without venting into the atmosphere, and at the end of the gas gathering pipeline, the specific liquid content (α _t ) in the gas is measured using a droplet separator. The gas is separated and supplied to the inlet of the complex gas treatment unit during the time period of the purge until the specific liquid content (α _t ) decreases to the value α _t = α _min , which is determined in advance, and the time of the purge period is recorded. Simultaneously measure the density (ρ _w ) and the total volume (V _pr ) of the separated liquid. At the end of the purge period, the gas gathering pipeline is switched to the current operating mode, at which the gas flow rate in the pipeline (q _g ), the specific liquid content (β ₀ ) in the gas at the beginning of the gas gathering pipeline and the gas temperature in Celsius at the inhibitor injection points are measured. At the first point along the direction of gas flow from the wells, at which the gas temperature in Celsius is negative, an ice inhibitor is supplied. Then, after a time τ = (V _CR × ρ _W ) / (β ₀ × q _g ), the inhibitor supply is stopped and the gas gathering pipeline is purged with gas from the wells side again without venting into the atmosphere during the purge time period fixed during the initial purging. At the end of the purge period, the gas gathering pipeline is transferred to the current operating mode.

In the above method, methanol is used as an ice formation inhibitor.

In the above method, glycols are used as ice formation inhibitors.

In the above method, concentrated electrolyte solutions are used as an ice formation inhibitor.

In the above method, mixtures of methanol, glycols and concentrated electrolyte solutions are used as an ice formation inhibitor.

The invention is illustrated by the figures, which schematically depict:

in fig. 1 - a variant of inhibition of the gas gathering pipeline at the beginning of the pipe without blowing (traditional method);

in fig. 2 - a variant of inhibition of the gas gathering pipeline without blowdowns with the possibility of supplying the inhibitor selectively to several points of injection;

in fig. 3 - a variant of inhibition of the gas gathering pipeline with blowdown (with the possibility of supplying the inhibitor selectively to one injection point).

FIG. 1, 2 and 3 show a gas gathering pipeline 1 connecting production wells or well clusters with an integrated gas treatment unit (CGTP, which is not shown in the diagrams). In addition, for the implementation in practice of the claimed method, an inhibitor supply device is required, the terminal element of which is an inhibitor line 2, laid along the gas gathering pipeline 1. Position 3 shows the accumulation of liquid in the gas gathering pipeline 1, and position 4 - a dangerous section of the gas gathering pipeline 1 located before the start a section of a gas gathering pipeline with a negative Celsius gas temperature.

It should be noted that the implementation in practice of the claimed method is possible with the help of a technical system, which consists of standard elements, assemblies and assemblies that can be equipped with oil and gas industry enterprises. In particular, the system for preventing ice formation in the gas gathering pipeline includes, along with the inhibitor supply device, a flow meter and a control station, which receives information from sensors measuring the gas temperature at the inhibitor injection points. The inhibitor can be supplied to one of the provided inhibitor injection points, selected according to the thermal regime of the gas gathering pipeline. Specifically, the point of injection of the inhibitor is set by the control station before the beginning of the section of the gas gathering pipeline with a negative Celsius gas temperature. The system includes a device (subsystem) for blowing the gas gathering pipeline, a two-phase separator and a flow meter for the separated liquid (liquid meter). In addition, the system is equipped with drip eliminators.

The method is carried out as follows.

In the winter season, before the start of the inhibitor supply, the gas gathering pipeline is purged by switching the gas flow with the accumulated liquid to the blowdown line in order to remove practically all the accumulated liquid from the gas gathering pipeline. The gas gathering pipeline is purged from the side of the wells by reducing the pressure in the purge line down to atmospheric. At the same time, a gas velocity is created that is 1.5-2.5 times (but not more than 20 m / s), the critical velocity, which ensures the removal of liquid in the gas gathering pipeline.

The purging is carried out without venting the gas into the atmosphere with the flow of the aqueous phase into the two-phase separator. In this case, the purge gas is returned to the gas preparation process cycle, for example, using a compressor with a high compression ratio. In the process of performing the purge, the total volume of the liquid V _pr (m ³ ) taken out into the separator is measured according to the readings of the flow meter of the separated liquid. The density ρ _w (kg / m ³ ) of the separated liquid is determined according to known methods in the laboratory. The gas is separated and fed to the inlet of the complex gas _{treatment unit during the time period until the specific liquid content α t} (kg / m ³ ) in the gas decreases (Istomin V.A., Tipugin A.V., Mitnitskiy R.A., Ismagilov R .N., Control of liquid content in gas wells production // Gas industry / special issue 633, 2009, pp. 34-39) to a value equal to a predetermined value of α _min (kg / m ³ ), corresponding to the maximum possible purified from liquid accumulations the pipeline, and the duration of the purge is recorded in terms of time t (hour). Next, the gas gathering pipeline 1 is transferred to the current operating mode of its operation and the supply of methanol is resumed through the inhibitor pipeline 2 immediately before the section of the gas gathering pipeline where ice formation is possible.

To control the inhibitor flow rate in automatic mode and select a specific inhibitor injection point, the system has a control station to which information is supplied from gas temperature measurement sensors at the inhibitor injection points. The inhibitor is fed to one of the provided inhibitor injection points, selected according to the thermal regime of the gas gathering pipeline. Specifically, the point of injection of the inhibitor is set by the control station before the beginning of the section of the gas gathering pipeline with a negative Celsius gas temperature. At the command from the control station, the inhibitor is supplied directly in front of the section of the gas gathering pipeline, where ice formation is possible.

The specific consumption of the inhibitor is set taking into account the specific amount of condensation water β ₀ (kg / m3 ^of gas) falling between the point of supply of the inhibitor and the end of the gas collection pipeline, measured in the gas at the beginning of the gas collection pipeline 1. This amount of water is significantly less than the amount of all water, entering the gas gathering pipeline from the well cluster. The thermal parameters of the gas gathering pipeline measured by the gas temperature measurement sensors determine that part of the gas gathering pipeline that operates in the ice formation mode. The required point of injection of the inhibitor is selected according to the thermal regime.

The required specific consumption of the inhibitor is calculated according to standard methods (see Istomin V.A., Kvon V.G., Troynikova A.A., Nefedov P.A.Peculiarities of preventing ice and hydrate formation in gas gathering systems at the late stage of operation of Cenomanian deposits deposits of Western Siberia. Transport and storage of petroleum products and hydrocarbons, No. 2, 2016).

In this case, the specific consumption of the inhibitor turns out to be significantly reduced, since the inhibitor is not diluted with formation water coming from the well (since water accumulates in the lowered sections of the gas gathering pipeline to the point of injection of the inhibitor). In fact, the flow rate of the inhibitor is set only by taking into account the water condensing from the gas phase. Thus, the specific consumption of the inhibitor is reduced by several times.

During further operation of the gas-gathering pipeline emptied from the liquid water phase, there is a gradual accumulation of liquid in it in the lower initial sections of the gas-gathering pipeline. Thus, the initial sections of the gas gathering pipeline (where, according to the thermal modes of its operation, the mode of operation without ice formation is realized) function for a certain time in the mode of accumulating liquid with a temperature above zero degrees Celsius.

With the accumulation of liquid in the initial section of the gas gathering pipeline, there is a risk of water getting into the section of the pipeline already inhibited from ice. With the emergence of this risk, it is necessary to carry out the next purge cycle of the gas gathering pipeline with the transition to the standard mode of its operation.

The next cycle of purging and subsequent inhibition of the gas gathering pipeline is performed over time:

τ = (V _pr × ρ _w ) / (β ₀ × q _g ), (hour),

where V _pr is the measured total volume of the separated liquid (m ³ );

ρ _w - the density of the separated liquid (kg / m ³ );

β ₀ is the specific liquid content in the gas at the end of the gas gathering pipeline, completely cleaned of liquid accumulations (kg / m ³ );

q _g - gas consumption in the current mode (m ³ / hour).

Implementation of the proposed invention ensures reliable operation of field pipelines at a late stage of field development in difficult conditions (accumulation of liquid in lowered sections of the embossed pipeline route and lowering the gas temperature below zero degrees Celsius with the possibility of ice formation in the pipeline cavity). In addition, the savings (economy) of the ice inhibitor is provided.

Claims (5)

1. A method of preventing ice formation in a gas-gathering pipeline, which consists in the fact that an ice-formation inhibitor is supplied to the gas-gathering pipeline, characterized in that the gas-gathering pipeline is initially purged with gas from the side of the wells without venting into the atmosphere, while the specific liquid content α _{t is measured at the end of the gas-gathering pipeline} in the gas, and the gas separated during the time the purge period to reduce α _t specific liquid content to a value α _t = α _min, which is determined in advance and fixed while purging period measured density ρ _w and the total volume V _ave separated liquid, whereupon the gas gathering pipeline is transferred to the current operating mode, at which the gas flow rate in the pipeline q _{g is} measured, the specific liquid content β ₀ in the gas at the beginning of the gas gathering pipeline, the gas temperature in Celsius at the inhibitor injection points and at the first point along the gas flow direction from the wells, at which gas temperature in Celsius is negative The values are fed icing inhibitor, wherein after a time τ = (V _ave × ρ _g) / (β ₀ × q _g) stopping supplying the inhibitor and again purged gas supply line gas from wells hand without release into the atmosphere during the fixed during initial blowing period purge time, after which the gas gathering pipeline is transferred to the current operating mode. 2. A method according to claim 1, characterized in that methanol is used as an ice formation inhibitor. 3. The method according to claim 1, characterized in that glycols are used as ice formation inhibitor. 4. The method according to claim 1, characterized in that concentrated electrolyte solutions are used as an inhibitor of ice formation. 5. The method according to claim 1, characterized in that mixtures of methanol, glycols and concentrated electrolyte solutions are used as an ice formation inhibitor.

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