RU2255218C1 - Method for express determining of moisture containment level in product of gas wells - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method can be used in gas wells equipped with mouth brace, having mouth socket of manometer. Product is extracted at well mouth through mouth socket of manometer. Moisture containment level measurements for well product are performed immediately at well mouth. Said measurements of moisture containment of product are preferably performed using absorption-capacity method.

EFFECT: higher precision.

2 cl, 2 dwg

Description

The invention relates to the gas industry and can be used to determine the amount of water in the vapor phase contained in the production of gas wells to establish the nature of the processing of the geological section, predicting the process of watering the wells, assessing the quality of the waterproofing.

At present, control over watering of gas wells is reduced to determining the position of the surface of the gas-water contact (GWC) and is solved by the methods of field geophysics (GIS). For wells in the production of which the presence of formation water is recorded, the position of the GWC is determined by comparing the design of the well and the results of special studies. Until recently, it was not possible to predict the occurrence of produced water even in the near future (1.5-2 years) without performing calculations on a gas-hydrodynamic model / Gas-dynamic monitoring of well operation in gas fields and underground gas storages by field-geophysical methods: Methodical recommendations. -M.: Publishing House “OKHO of the Ministry of Oil Industry of the USSR”, 1991.160 p. /.

Geophysical control of the watering process has the following disadvantages: the high cost of research, the lack of a quantitative assessment of the water content in the well production. The number of available observational (non-perforated) and vertical active wells with geological faces at the level of the initial GWC, as a rule, does not provide a level of detail sufficient to effectively predict the water flooding of wells of the entire production fund. By the time the field enters the period of falling production, the situation is even worse due to the flooding of existing wells used for GIS control, waterproofing works with the installation of cement bridges that span the GWC interval, which makes it impossible to track its further progress.

A known method of gas condensate research of wells conducted at the wellhead, including the separation of products, the selection of liquid and solid phases for subsequent laboratory analysis, while gas condensate in the vapor phase is removed from the study site, collected and disposed of / Pat. 2081311RF, IPC ⁶ E 21 V 47/00, publ. 06/10/1997 /.

The method for determining the moisture content of well products by conducting special studies using known separation plants has the following disadvantages: significant gas release to the atmosphere, laboriousness, the need for constructive changes in the wellhead piping (for connecting separators), time-limited period of positive ambient temperatures.

All known methods do not record the presence of water in the vapor phase.

The task to which the claimed invention is directed is to develop a method that allows to quickly obtain information about the moisture content of gas well products practically without releasing gas into the atmosphere, without conducting additional geophysical and special studies, i.e. with minimal restrictions on the conditions of use, identify and quantify the presence of water in the production of gas wells.

When carrying out the invention, the task is solved by achieving a technical result, which consists in increasing the accuracy of determining the moisture content of gas well products by taking into account the vapor phase.

The specified technical result is achieved by the fact that in the method for the rapid determination of the moisture content of gas well products equipped with wellhead piping having a wellhead pressure gauge socket, including product sampling at the wellhead, the feature is that the product is sampled through the well head pressure gauge socket, and measurements are carried out to determine moisture content production of gas wells is carried out in the vapor phase directly at the wellhead. Measurements to determine the moisture content of gas well products are carried out by the sorption-capacitive method.

The causal relationship between the essential features of the invention and the claimed technical result is as follows:

The method is based on the effect of evaporation of water into gas when the thermobaric conditions change as a result of gas extraction from productive intervals. Measurements are taken directly at the wellhead with the removal of the analyzed gas through the wellhead of the pressure gauge.

It should be noted that the concept of humidity of produced gas is practically not considered as a value characterizing the process of field development. Typically, the moisture content of the gas that has been dried at the integrated gas treatment plants is characterized by a dew point, defined as the temperature at which the partial pressure of saturated water vapor is equal to the partial pressure of water vapor in the gas in question. However, this parameter is interesting mainly from the point of view of gas trunk transportation.

It is obvious that the moisture content of the gas from the surface of the GWC is constant, and in the displacement zone it is determined by the current thermobaric conditions that affect the evaporation of pore water into the produced gas. As GVK approaches the perforation interval or annular gas flow from the displacement zone, the moisture content of the produced gas will change, which can be recorded by the wellhead moisture meter. Since in this case, produced water in the production of gas wells is exclusively in the vapor phase, other methods of research will not give a result.

To carry out measurements to determine the moisture content of gas well products directly at the wellhead, a device was used, including an IVA-6 thermohygrometer, a sampling device for connecting to the wellhead harness through the wellhead of the manometer (UGM) and sampling the analyzed products directly in the field, recording instrumentation software for recording data. The composition of the thermohygrometer includes a primary transducer and a measuring unit connected by a flexible cable.

The IVA-6 thermohygrometer is made in accordance with TU 4311-001-18513042-01 and entered into the State Register of Measuring Instruments with registration number No. 13561-01. “Iva-6” is an automatic, digital, single-channel, multi-functional continuous thermohygrometer. The primary transducer of a thermohygrometer contains sensitive elements of humidity and temperature (for example, a silicon digital sensor) and a capacitance-frequency humidity transducer. The stand for calibration and calibration of the device by the humidity channel is based on the Rodnik 2 reference gas humidity generator, the Baikal type coulometric hygrometer gas measuring dry gas weighing circuit, and serves as a reference standard in the humidity measurement range and allows for automatic calibration. “IVA-6” has a dew point measurement range from -50 to + 50 ° C with a lower limit of the humidity range of at least 0.03 g / m ³ .

The method is based on the following physical premises.

To measure relative humidity (as an indicator of the vapor phase), a sorption-capacitive sensitive element is used, the principle of which is based on the dependence of the dielectric constant of the polymer moisture-sensitive layer on the humidity of the environment. The output frequency (Fe) of the humidity transducer is related to the measured relative humidity ψ by polynomial functions:

ψ = ψ ₀ + k ₁ (F _at -F ₀ ) + k ₂ (F _at -F ₀ ) ² + k ₃ (F _at -F ₀ ) ³ ,

where ψ is the relative humidity,%;

ψ, k ₁ , k ₂ , k ₃ , F ₀ are the polynomial coefficients, the values of which are determined during the calibration of the device.

In the device, the calibration characteristic of the humidity sensor due to its nonlinearity in the low concentration region is described by two polynomials of the third degree, the coefficients of which are determined during the calibration, for the ranges of measuring relative humidity of 4-100% and 0-4%. Calibration data is stored in the non-volatile memory of the microcontroller.

The absolute humidity of the gas A (g / m ³ ) is associated with its relative humidity by the following relationship:

A = 6.2198 ψP _S / (10000 (E + 273.16)

where P _S is the partial pressure of saturated water vapor, (Pa), at temperature T (° С)

Example. Field tests were carried out on Yambursky. In total, more than 740 measurements of product humidity (gas flow) at the mouth of gas wells were performed. The measurements covered over 500 wells.

Field measurements of the moisture content of gas well products were carried out using a mobile laboratory. The selection of products was carried out through the wellhead of the manometer (UGM) in the wellhead system with subsequent release to the atmosphere. To connect the sampling device to the production line of the well through the UGM, a high pressure hose with preliminary closing of the UGM shutoff valves was used. The gas pressure at the humidity sensor was maintained at 1 at. The measurements were carried out at ambient temperature from -20 ° С to + 30 ° С. The duration of the determination of moisture content was 60 minutes with a working well.

The measurement results are presented in the form of graphs, in which Fig. 1 shows graphs of measuring humidity 1 of a gas well production and temperature 2, made in order to assess the quality of waterproofing works, Fig. 2 shows graphs of measuring humidity 1 of a gas well production and temperature 2, made within the framework of monitoring the development of a deposit at a certain time interval (measuring points).

The measurement results presented in figure 1, indicate that in this case, the waterproofing is poor. Excess water content was recorded in well production.

The average relative humidity of 0.30 g / m ³ in one of the studied wells indicates that this well is dry, the upper part of the section is being worked out, excessive moisture content is not observed (see figure 2).

Thus, the determination of moisture in the vapor phase indicates that the product comes from the zone of undersaturation (surface area of the gas-water contact). Consequently, it is possible to quickly control the process of watering the reservoir, i.e. to identify the interval of the reservoir with a large gas content floor, quickly determine where, from what interval, from what depth the gas well products come from, and develop appropriate geological and technical measures. The method can be used as an express method for determining the moisture content of gas well products in the process of monitoring field development. In this case, the determination of moisture content can be combined with other well studies. The effectiveness of the method is determined by the reduction in the number of laboratory tests due to the expansion of field research, increased accuracy and low emissions into the atmosphere.

Claims (2)

1. The method of rapid determination of the moisture content of gas well products equipped with wellhead piping having a wellhead pressure gauge socket, including the selection of products at the wellhead, characterized in that the selection of products is carried out through the wellhead pressure gauge socket, and measurements to determine the moisture content of gas well products are carried out in the vapor phase directly at the wellhead. 2. The method according to claim 1, characterized in that the measurements for determining the moisture content of gas well products are carried out by a sorption-capacitive method.

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