RU2484503C1 - Method for helium survey on water bodies - Google Patents

Abstract

FIELD: chemistry.SUBSTANCE: water body is profiled. Water samples are collected from a given depth by sucking. The sample is fed for separation by a continuous stream. The gas phase of the sample is separated while discharging the degassed liquid. The gas phase of the sample is fed into a gas analyser. The desired gas is extracted from the gas phase of the sample. Its concentration in the sample is measured. The investigated area of the water body is mapped based on data on concentration of the desired gas. The desired gas used is helium. The gas analyser used is a membrane type helium leak detector. Water samples are collected near the bottom of the water body while controlling the depth at which the samples are collected. Helium concentration is measured by at least two helium leak detectors successively in cyclic mode. Duration of the measurement cycle is established based on the condition of excluding the effect of drift of the helium leak detector on the measurement. The interval between measurements in the cycle is established based on data on the geologic structure of the bottom of the investigated water body. Duration of each measurement in the cycle is selected greater than the period of time for measuring background concentration of helium in water. Background concentration of helium in the water is determined before profiling the water body.EFFECT: high efficiency of mapping a water body via helium survey, high accuracy of analysing bottom water samples.2 cl, 3 dwg

Description

The invention relates to one of the types of gas-geochemical methods of mineral exploration - helium imaging, and can be used to identify promising oil and gas objects and zones of improved fracture permeability of the geological section within the water area.

It is known that helium, which dissolves well in water, is an indicator of the structural features (fracturing, porosity, etc.) of rocks that make up the bottom of the water area, and with increasing water pressure (at the depth of the water area), the solubility of helium increases significantly in comparison with the content in the surface layer water, and the presence of other gases (nitrogen, methane, etc.) in water increases the solubility of helium in water.

To analyze the bottom structure and search for mineral deposits in the water areas, indirect methods are usually used - seismic, gravimetric, etc. / for example, WO 2009055918 /, based on the differentiation of the measured physical characteristics of the bottom areas, as well as methods of geochemical studies of the prevalence of satellite elements hydrocarbons / SU 894657, RU 2226282, RU 2417387, US 4890486 and others /.

Gas-geochemical surveying provides for water sounding of the water area and water sampling from the bottom layer and from bottom sediments with the subsequent study of the component composition of samples directly on board the vessel by express methods / Tkachenko G.G. et al. Geochemical methods for searching for oil and gas offshore. In Sat “Geology of the seas and oceans. Materials of the XVII International scientific conference (School) on marine geology. Moscow, November 12-16, 2007. " Areal gas surveys during the search for hydrocarbons can identify anomalies of gaseous and liquid hydrocarbons in the medium, monitor the water area, map the zones of activation of geodynamic processes or technogenic pollution.

The areal gas survey in the water area is carried out by sensing the water column using a CTD probe with a methane sensor, the bottom sediments are tested by a side scorer, from which surface sediments and sediments are taken in the range of 25-30 cm, and bottom water is taken from the side scorer and a bathometer,

The selected samples are delivered on board the vessel, the sediment and water samples are degassed, and the concentration of the gas component of the samples is determined / G. Tkachenko. et al. Ibid. The disadvantage of this method is the limited functionality due to the determination of only the methane content, which reduces the information content of the survey.

A known method of a comprehensive gas-geochemical study of water areas in order to identify promising oil and gas areas and a direct search for hydrocarbons, which involves the use of surface floating means for continuous profiling of the water towed in the bottom water layer of an underwater vehicle equipped with analyzers, sampling water from the bottom layers of the water area, isolating dissolved samples from the sample gas separation of gases using selective membranes and measurement of absolute dissolved Hydrocarbon indicator gases in the water /www.inno-expert.ru/projects/. As a towed underwater vehicle, remote-controlled or tethered underwater vehicles can be used, connected to the towing vessel through an intermediate deepener. The choice of the type of underwater vehicle is usually determined by the depth of research and the area of the area under study, so a remote-controlled underwater vehicle is capable of maneuvering over a large territory, unlike a tethered underwater vehicle. As a gas analyzer, in particular, the MAGMASS system (MASS-Spectrometric marine gas analyzer) can be used, which provides gas-geochemical analysis directly in the sampling area, as well as the transfer of pre-processed analysis results via a communication line to the on-board processing unit for building maps of the distribution of the required elements and identifying anomalies. Mass spectrometric method of gas analysis allows you to select helium in the gas phase of a water sample, however, in general, this research method is not only very expensive due to the use of underwater instruments, but also introduces errors in the measurement results due to disturbance of the medium by the very fact of the presence underwater vehicle in the study area.

The known method of helium shooting in the water / Yanitsky I.N. Helium shot. M .: "Nedra", 1979 /, which provides for sampling discrete water samples at a given depth of the water using a suction pump, supplying the sample to the inlet, degassing the sample with the removal of the gas phase, the separation of helium from the gas phase, quantitative determination of the helium content in the sample, determination the spatial distribution of helium by the totality of measurements at given points in the profile, which is used to judge the disturbed structure of the lithosphere. The method is characterized by insufficient accuracy, because the helium content is determined as excess relative to the gas dissolved in the water / according to the Savchenko method /, but with local sampling of water samples, the concentration of gases that increase the solubility of helium (methane, nitrogen) can change.

A known method of marine gas geochemical studies used to detect submarine hydrocarbon deposits, including profiling the surface of the surface with a floating vessel, sampling sea water from a predetermined depth by suction, supplying it for separation in a continuous stream, separating the gas phase under reduced pressure and draining the degassed liquid, supplying gas phase to the gas analyzer, which is used as a chromatograph, and to the sample analyzer - flame-ionization chamber - to determine the content of carbohydrate Orodes in the sample / US 3681028 /. In case of detection in a certain area of increased concentrations of the desired gases, an additional analysis of the sea soil in this area for the hydrocarbon content is carried out. The known method allows continuous analysis of samples of sea water also with the determination of helium content in it and to examine large areas of the water area, obtaining a result in real time, but the need for additional involvement of soil studies in the interpretation of the results increases the cost of time, materials and funds. The content of the components in the gas phase of the sample is determined by the chromatograph on a small volume of gas, which reduces the accuracy and reliability of the analysis.

A known method of marine gas-geochemical studies, including profiling of the water area, taking a water sample from a predetermined depth by suction, supplying the sample for separation by a continuous stream, separating the gas phase of the sample while draining the degassed liquid, supplying the gas phase of the sample to the gas analyzer, extracting the desired gas from the gas phase, measurement of its concentration in the sample and mapping of the studied area of the water area according to the concentration of the desired gas in water samples is selected as the closest analogue for the method being.

The objective of the invention is to improve the performance of mapping the water area (sea, lake, river) through the use of helium imaging, as well as the accuracy and reliability of the analysis of bottom water samples from the water area.

The problem is solved in that in the method of offshore gas geochemical studies, including profiling the water area, taking a water sample from a given depth by suction, supplying it for separation by a continuous stream, separating the gas phase of the sample with simultaneous discharge of the degassed liquid, supplying the gas phase of the sample to the gas analyzer, and isolating the desired gas from the gas phase of the sample, measuring its concentration in the sample and mapping the studied area of the water area according to the concentration of the desired gas, in accordance with the invention, as and helium is used as a gas analyzer, a membrane-type helium leak detector is used, a water sample is taken near the bottom of the water area to ensure control of the sampling depth, the helium concentration is measured by at least two helium leak detectors in turn in a cyclic mode, and the duration of the measurement cycle is determined from conditions for eliminating the influence of helium leak detector drift on measurements, the frequency of measurements in a cycle is established on the basis of data on the geological structure of the bottom of the surveyed water area, and the duration of each measurement in the cycle is chosen to exceed the time interval for recording the background concentration of helium in water, and the background concentration of helium in water is determined before the profiling of the water area begins.

In addition, a Varian helium leak detector PHD-4 is used as a helium leak detector.

The invention is illustrated in figure 1-3, which presents: figure 1 is a known distribution diagram of the concentration of helium in various environments (formation water - curve 1, liquid hydrocarbons - curve 2, free gas - curve 3), figure 2 - scheme conducting helium surveys in the water area, figure 3 is a map of the water area of Lake Ladoga Bay with a plot of adjacent land and a map of the distribution of helium according to helium surveys in this area.

The technical result of the invention is to increase the information content of the analysis by using as a search feature the distribution of helium content in bottom water and continuous measurement of helium content in samples with overlapping operation of helium leak detectors to exclude periods of "dead" time in the measurements.

The invention is based on various absorption of helium by oil, free gas and water, proportional to the solubility of helium in these environments.

The frequency n of occurrence of average concentrations of helium C in samples of various media is shown in Fig. 1 / A.N. Voronov et al. Oil and gas geology. Proceedings of VNIGRI, August, 1982). Therefore, when continuously recording the profile of helium concentration in the bottom water sample, the distributions correlating with hydrocarbon deposits and also with the tectonic disturbance of the overburden (the near-surface zone of the sedimentary cover) or with their weak efficiency with respect to helium (the profile of helium concentration is shifted upwards) will be separated concentration compared to its concentration in water).

The method is carried out using the device (figure 2), which includes a floating device (1) in the form of a self-propelled or towed vessel, a water sampling line (2) with a sinker to ensure the desired distance of the sampling point from the bottom of the water area and coarse and fine filters samples from impurities of various origins (suspension, sand, detritus, algae, etc.) and a pressure sensor mounted at the end of the submersible section of the water sampling line. A pressure pump (3) is placed on the vessel (1) for the continuous supply of bottom water to the degassing and separation device of sample (4), which is formed by several gas-liquid separators installed in parallel and combined by a bottom water supply and a degassed liquid discharge line. To ensure stable parameters of the gas flow (temperature, pressure and flow rate) supplied to the analyzers of the gas composition of the sample (5), it is advisable to install several, for example three, such devices. The gas phase of the sample after separation from the liquid enters the gas analyzer of the sample composition (5) through gas pipelines, formed by at least two membrane-type helium leak detectors that extract helium from the gas phase, passing through the membrane, produce a signal proportional to the helium content in passing through the device gas flow, and do not let other components of the gas mixture pass. Helium leak detectors are connected to the analysis results recording device (6) in the form of a laptop computer, to which also a satellite navigation system (7) (GPS antenna type BU-353 (WGS84 system)) is connected to coordinate the coordinates of sampling sea water and a digital multimeter ( 8), which records the signals of the pressure sensor at the sampling point of the seawater and, using built-in software, converts the recorded current value into the depth of sampling. Computer (6) (for example, ASUS Eee PC701 laptop can be used) has special software for writing to a text file and archiving data on the helium content at the measurement point, in ppm; time of observations and geographical coordinates received from a GPS antenna connected to a USB port using satellite signals, as well as for data transmission to coastal services.

A helium leak detector performs the process of measuring the helium content in the test gas, while two instruments take measurements one after another, which eliminates dead zones (periods of no observations on the underwater survey profile), eliminates drift of single instrument readings due to continuous operation. The portable helium leak detector model PHD-4 of the company Varian (USA) provides measurement of the concentration of helium gas He in the sample up to a minimum value of 2 ppm (2: 1,000,000 particles). In the selected model, the analyzed gas through the sample feed channel enters the membrane pump, passing only helium atoms through the quartz membrane into the helium detector. The detector in the form of a chamber with electrodes is connected to a high-voltage element providing the voltage required for the measurements on the electrodes and connected through an amplifier with a microprocessor, to which a membrane pump and an exhaust gas heater are also connected, which ensures its removal. The microprocessor is controlled using the on-screen keyboard. The arrival of helium atoms in the detector chamber is accompanied by the appearance of an electrical signal proportional to the partial pressure of helium, which registers the microprocessor and converts the signal to the current helium concentration in the sample. The response time of the device is less than 2 s, the maximum signal drift is 10 ppm / 10 min, the operating temperature range is from + 5 ° C to + 35 ° C, the battery continuous operation time is 4 hours. The diaphragm pump for the selected model of a helium leak detector has regular means of backflushing to restore efficiency after measurements. The choice of this model of a helium leak detector is determined by the ease of use - the samples taken are analyzed directly on site, are not accumulated and are not stored, in contrast to the known samples of helium leak detectors of mass spectrometric and manometric types, which increases the reliability of analysis and reduces the cost of work. In addition, when using this model of a helium leak detector, it is possible to organize a telemetric communication channel between the wireless module connected to it via digital input / output RS232 - the LM048 Bluetooth adapter and the computer Bluetooth interface unit (6).

The helium shooting method is as follows. A floating device, such as a self-propelled vessel (1), is prepared for field work. In the aft part of the deck of the vessel (1), a stationary electric winch (10) is installed permanently with a cable system including a steel cable bay (9), a guide roller (11) is mounted on the edge of the stern to release the steel cable. A sampling line is assembled consisting of: a seawater sampling line (2) with a sinker (12), a centrifugal pressure pump (3), a gas-liquid separator block (4), and connect it to the seawater analyzer (5) - helium leak detectors.

Before starting work, a sensor for the depth of sampling water is calibrated (13), determining the relationship between the immersion depth of the sensor and the value of direct current passing through the measuring circuit of a digital multimeter (8), and calibration is performed at the deepest point in the water area in the survey area.

Then, the background concentration of helium in water is measured in the field of work by sampling at various depths from the surface (in the field of concentration equalization) and at different points in the water area using standard equipment. The water sample is degassed, the gas phase is diverted to helium leak detectors, which measure at each given point in the water area from the time the gas phase is supplied to the membrane pump until the steady-state electrical signal corresponding to the current concentration of helium in the sample is established. A series of measurements determines the average value of the background concentration of helium in water in the mapping zone and the time interval necessary for recording the value of the background concentration of helium using the selected device. In this case, the number of measurements in the series (at least 30) should be sufficient to minimize the variance of the background helium concentration.

After preparatory operations at the site of work from the vessel (1) using an electric winch (10), the reinforced hose of the water sampling line (2), duplicated by a steel support cable (9) and weighed down by a sinker (8), is lowered to a specified depth at the bottom of the water area. Sinker (12) is type-set and immerses the hose of the sampling line (2) to any desired depth, so that the sinker (12) touches the bottom and when moving the vessel (1) monitors the bottom profile, preventing the hose from changing the immersion depth and not causing noticeable disturbances of the bottom layers of water. The need for a bottom sampling of water (isogypsum can take place at a distance of about 1 m from the bottom) is due to high gradients of the concentration of helium and other gases in the places where fluids exit through tectonic disturbances in the layers of the bottom of the water area. The depth of sampling is controlled in real time according to the readings of the pressure sensor (12) transmitted to the computer (6) through a digital multimeter (8). The injection pump (3) is turned on and air is pumped out in the hose to take a sample in the form of a stationary stream of water from a given depth of the water area. When a water sample is taken in a continuous stream, it is cleaned with coarse and fine filters (in front of the discharge pump (3)). A continuous stream of liquid enters the gas-liquid separators (4) for degassing, for example, of a thermal vacuum type, in which the liquid is sprayed, the gas phase is separated and fed into the gas outlet for subsequent analysis of the composition. Degassed water enters the discharge line and is discharged overboard, the gas phase is analyzed by helium leak detectors (5). These devices are connected in turn to exclude the influence of the drift of its readings (for the selected model of leak detectors, the drift is 10 ppm / 10 min) on the measurement results. Each device takes measurements in cycles - at least 30 measurements in each cycle - to ensure statistical reliability of the results. The duration of each measurement in the cycle is chosen to be the same and exceeding the time interval for recording the background concentration of helium in water, taking into account the response time of the device (5) (at least 2 s), which corresponds to the transmission of equal volumes of liquid through the degasser (4) and gives an adequate volume of the gas phase of the sample for analysis. As a result, the measured helium concentration corresponds to the number of helium particles in a certain quantized volume of bottom water along the route, determined by the instantaneous volume of sampling the water and the speed of the vessel. The time interval between two consecutive measurements in a cycle is established on the basis of preliminary and independent information about the geological structure of the bottom of the water area, in the case of a complex geological structure, measurements can be carried out quite often, an alternative is to take measurements at specified intervals while reducing the speed of the vessel along the profile.

Using the developed device, we conducted a study of the fracturing of rocks in the water area of one of the bays of Lake Ladoga according to the underwater helium survey (with access to land for additional control of the analysis results). Helium survey was carried out over a network of profiles from a moving vessel, the speed of which did not exceed 3 km / h in order to avoid lifting the sampling line with cargo to the surface of the reservoir, and was monitored using GPS antenna data. The distance between the profiles was determined by the geological exploration of the area and its size and amounted to 200 m. Previously, the background concentration of helium in the water of the bay (as described above) was determined, which was 3.2 ppm, the recording time was 2.5 s. The number of measurements in each cycle was set equal to 30, the interval between measurements was 3 s. The research depth did not exceed 220 m, which was due to a combination of parameters - the length of the sampling line, the weight of the load, the power of the winch, etc. Water samples were taken continuously from a depth of not more than 1 m from the bottom (the sinker slid along the bottom), while neglecting horizontal underwater currents and the drift of gas bubbles. When processing field data, the coordinates of the vessel recorded by the GPS antenna were recalculated into the coordinates of the sampling points. Under these research conditions, the helium content in the bottom layers of the water area of the bay was recorded along predetermined paths and, by interpolating the values of helium content at the points of adjacent paths, a map of the distribution of helium concentration in the bottom layer of the studied water area was constructed (Fig. 3 shows a map of the distribution of bottom helium concentration in excess of background values). A map of the helium survey of the bay showed areas of increased helium content in the samples in the northeast – southwest direction in the water area. Areas of increased helium concentration on land in the coastal zone of Lake Ladoga were identified earlier, a joint analysis of the results of land and underwater studies made it possible to unequivocally interpret the result in terms of the unity of the geological structure of this region. In addition, the obtained map of the distribution of helium in the bottom areas of the water area revealed local areas in which the helium content many times exceeded the background values, which was interpreted as the presence of zones of increased fracturing of rocks that make up the bottom of Lake Ladoga.

During production, helium survey profiles can be worked out according to the profiles of seismic and other geophysical works for their correlation. When anomalies are detected, the network of profiles is thickened by a factor of 2-4, while the estimated timeline for performing helium underwater surveys on an area of about 100 sq. km with a distance between the profiles of 100 m, the speed of the vessel 3 km / h (taking into account preparatory work, field observations, processing and interpretation of the results) is about 800 hours. In the case of large depths of the water area or complex structure of the bottom, it is possible to draw water at a certain distance from the bottom (isogypsum) in the presence of a gradient of helium concentration, while the distance of the tip of the sample supply hose from the bottom can be maintained in a known manner, for example, by adjusting its buoyancy by attaching ballast tanks. In the field, the device has proved its effectiveness and can be recommended for use in the study of geological structures and the search for hydrocarbons on the marine shelf, seas, lakes and rivers.

Claims (2)

1. The method of marine gas-geochemical studies, mainly helium surveying, including profiling of the water area, taking a water sample from a given depth by suction, supplying it for separation by a continuous stream, separating the gas phase of the sample with simultaneous discharge of the degassed liquid, supplying the gas phase of the sample to the gas analyzer, isolating the desired gas from the gas phase of the sample, measuring its concentration in the sample and mapping the studied area of the water area according to the concentration of the desired gas, characterized in that as helium is used as the gas analyzer, a membrane-type helium leak detector is used, a water sample is taken near the bottom of the water area to control the sampling depth, the helium concentration is measured by at least two helium leak detectors alternately in a cyclic mode, while the duration of the measurement cycle is determined from conditions for eliminating the influence of helium leak detector drift on measurements, the interval between measurements in a cycle is established on the basis of data on the geological structure the bottom of the surveyed water area, and the duration of each measurement in the cycle is chosen to exceed the time interval for recording the background concentration of helium in water, and the background concentration of helium in water is determined before the profiling of the water area begins. 2. The method according to claim 1, characterized in that as the helium leak detector of the membrane type use a helium leak detector model PHD-4 from Varian.

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