RU2667470C1 - Mobile vacuum disintegrator samples of bottom sediments and soils - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to gas geochemical studies of soils and can be used to solve geological, geophysical, oceanological, acoustic problems and engineering design. Device includes a disintegration chamber with metal balls rigidly connected to the system of introducing the sample of the sediment into it, with the inlet of the chamber being interfaced with the inlet of the receiving vessel. Sample introduction system is a technological frame between its upper and lower bases are installed a removable receiving vessel. Upper frame base is provided with means for connecting to the base of the degassing chamber and an opening associated with the inlet of the chamber, and the lower frame base is a piston with a screw thread interfaced to the thread in the process frame, that is arranged to move in a receiving vessel in the form of a cylinder equipped with a removable vacuum insert.

EFFECT: increase in the intensity of gas-chemical studies of large areas is achieved, especially in expeditionary conditions.

4 cl, 2 dwg

Description

The invention relates to gas-geochemical studies of soils and can be used during gas-geochemical surveys to identify gaseous and liquid hydrocarbon anomalies on the seabed surface as indicators of forecasting and searching for hydrocarbon deposits, gas hydrates, and solving other geological, geophysical, oceanological, acoustic problems and engineering design

It is known that by changing the composition of natural gas in bottom sediments and in the bottom layer of water, the ratio of the concentrations of its components, seismic activity is estimated, fault zones, bottom surface disturbances are determined, earthquakes are forecasted, and they are used in the engineering design of construction on the seabed.

When conducting a gas-geochemical survey of an object using geological tubes, soil samples are taken, including to extract gas from them, which is then analyzed on a gas chromatograph, determining the composition, quantity and ratio of gas components.

There are two ways to determine the concentration of gas components in the cores of bottom sediments, selected by a geological pipe from the bottom of river valleys or the sea - vacuum and vacuum-mechanical. When implementing the first method, various degassing installations are used, in which the intensification of the process of extracting gases from the sample is provided by heat treatment, for example, degassing installations according to A. SU No. 422843, 880995, 1505899. The disadvantage of this method is, firstly, the formation of new gas components during thermal exposure, which interfere with the correct determination of the natural gas composition, and secondly, the duration of the method in these installations and not taking into account the physical characteristics of the released gas components for example, methane leaves the solution quickly enough, heavy hydrocarbons (C2-C4) are very slow. The results are affected by changes in temperature, gas pressure inside the sample container, changes in the volume of the sediment sample, the amount of gas in the sediment sample, and other characteristics.

Vacuum-mechanical installations are known, which are based on the destruction of the sediment sample using various types of disintegrators without heat treatment of the samples. The main problem of these methods is the incorrect sampling of bottom sediments, which during the sampling and placement of the sample in the installation may lose a significant part of the gas.

A known installation for processing soil samples for the subsequent determination of gas saturation, in which a gas-liquid supersonic ejector is installed as a disintegrator of the soil sample. The installation contains two circuits: the main one is the degassing of water and the solution obtained after soil preparation, which includes a receiving tank, a pump, an ejector, and a gas collector, and an auxiliary soil degassing circuit connecting the distribution head of the soil sample preparation unit to the receiving tank, pressure pipe, and vacuum line, (p. of the Russian Federation No. 2348931). The disadvantage is the complexity and length of the gas extraction process, which leads to gas loss and, most importantly, loss of lighter gases - methane, helium, hydrogen, which are important as indicators of the source of gas supply from the mantle, hydrocarbon deposits, volcanic foci.

A known vacuum disintegrator, which is considered by us as the closest analogue. The disintegrator contains a vacuum chamber made of organic glass to place a sediment sample with a lid equipped with a fitting with a vacuum valve for evacuating the gas phase, connected to a vacuum degasser. The vacuum chamber is equipped with a hardened steel punch for the complete destruction of the glass container, in which the sample is in a sealed state (item No. 2007142968, published on 05.27.2009). By increasing the area and reducing the thickness of the degassed layer, distortions in the quantitative ratio of gas components in the gas mixture are eliminated and the degree of degassing increases. One of the significant disadvantages of this installation is the need to seal a glass container with a sample and the duration of the degassing process. It is especially difficult to use this device in expeditionary conditions at sea on a ship.

Thus, there is the problem of expanding the arsenal of means for extracting gas from samples of bottom sediments and soils during gas-chemical surveys of the studied surface.

The technical result is a new version of a mobile vacuum disintegrator of samples of bottom sediments and soils, followed by analysis of the extracted gas on a chromatograph, mainly for use in field conditions.

The problem is solved by a vacuum disintegrator of samples of bottom sediments and soils, including a disintegration chamber with metal balls inside, equipped with a cover with an opening equipped with a vacuum valve for evacuating the gas phase, and an inlet for introducing a sample located at the base of the chamber connected to the system for applying the test sample , which is a technological frame, between the upper and lower bases of which a removable receiving vessel is installed, the upper base of the frame is equipped with the connection with the base of the degassing chamber and the hole mating with the inlet of the chamber, and the lower base with a piston with a threaded thread mated to the thread in the technological frame, mounted with the possibility of movement in the receiving vessel, made in the form of a cylinder equipped with a removable vacuum liner, this one of the ends of the cylinder is equipped with an external annular limiter and an internal technological tide.

In FIG. 1 shows a General view of one of the possible options (prototype) of the inventive installation, and in FIG. 2 shows a disassembled installation, where a is a disintegration chamber with metal balls (not shown in FIG.), 6 is a sample injection system, and 1 is a camera body; 2 - cover; 3 - outlet opening of the cover with a vacuum valve; 4 - the base of the camera; 5 - camera inlet; 6 - racks of the technological frame; 7 - receiving vessel; 8 - piston, 9 - hole of the technological frame; 10 - fixing screws.

The device includes a disintegration chamber with metal balls that is rigidly connected to the system for introducing the studied sediment sample into it, while the inlet of the chamber is associated with the inlet of the receiving vessel and the openings of the technological frame.

The use of the claimed device is as follows.

The receiving vessel (7), with the liner located inside (not shown in the figure), the opposite end of the annular limiter, is gradually introduced into the core of the bottom sediment until the sample is completely filled, while the flexible vacuum liner of the vessel, moving along it until the technological tide, seals the opposite end of vessel. To facilitate entry of the cylinder into the core, the insertion end may be pointed. Then the vessel (7) with the sample is installed in the technological frame (6), placing its free end on the piston bottom (8), which ensures the sealing of the second end of the vessel (7). The resulting system (b) is rigidly connected by fixing screws (10) to the base (4) of the disintegration chamber, combining the inlet of the chamber (5) with the hole (9) of the upper base of the frame, i.e., in fact, with the opening of the receiving vessel closed by the liner. The disintegration chamber (1) with metal balls placed in it through the outlet (3) is evacuated by connecting to a vacuum pump. After evacuation of the chamber (1), the piston (8), screwing along the thread of the technological frame, moving along the vessel (7), extrudes a sediment sample into the chamber (1) through the opening of the receiving vessel (7) connected to the chamber together with the insert, while the inlet (5) the chamber is closed by the piston bottom (8), sealing the chamber from the external environment. Next, the installation is subjected to vibrational effects using any of the possible methods of mechanical shaking, including, for example, a shaker or manual shaking. Through the vacuum valve (3), the released gas is extracted from the chamber into a vacuum degasser for the subsequent determination of the gas volume and its chemical composition on a gas chromatograph.

The disintegration chamber can be made of any suitable material that can withstand a predetermined vacuum of 0.1 mm Hg, for example, organic glass. The number of metal balls is determined empirically. For example, it was experimentally determined that with a chamber volume of 100 ml, the precipitate is destroyed most qualitatively into tiny particles using 5 pcs. balls with a diameter of 6 mm and 5 pcs. with a diameter of 4 mm.

The connection of the chamber and the sample delivery system can be performed in any suitable manner, for example, as shown in FIG. 1, i.e. using fixing screws (10) and elongated struts of the technological frame passing through the openings of the base of the chamber. On the contrary, it is possible to equip the base of the camera with screws, and the frame posts are threaded to completely assemble the device.

The piston can be either metal or polymer, made, for example, from thermosetting or fluorinated polymers, such as PTFE, or ceramic materials. The connection of the chamber and the cover can be performed, for example, screw or threaded.

The inventive disintegrator is simple to manufacture and use, it allows to increase the mobility and efficiency of the scientific and practical geological studies in the study of the gas component in the lithosphere, making it possible in the field conditions to significantly reduce the time of the research, which is especially valuable in case of huge areas of ocean research for the presence of gas components of sediments , determine their qualitative and quantitative composition, which is then used as an indicator for solving geological x, environmental and other problems. The inventive installation was tested on an expedition to the R / V “Akademik Oparin”, flight Or52 in the Sea of Okhotsk in July 2017. The region of the Sakhalin north-eastern slope of the Sea of Okhotsk was examined and gas hydrates and gas bubble flows from bottom sediments were discovered. The analysis showed the presence of the following gases: methane - 200 ml / dm ³ , heavy hydrocarbons (C2-C4) - 100 μl / dm ³ , which exceeds the background by 100,000 times, as well as CO ₂ , O ₂ , N ₂ , N ₂ , Not . Typically, anomalies of methane and heavy hydrocarbons characterize the presence of oil and gas deposits, gas hydrates, carbon dioxide is an indicator of active volcanic and mud-volcanic activity, hydrogen and helium characterize the flow of gas from the lower crust and mantle and seismic activation, methane and carbon dioxide are greenhouse gases and are involved in global process of change, climate warming.

Claims (4)

1. Vacuum disintegrator of samples of bottom sediments and soils, including a disintegration chamber with a grinder located inside, equipped with a cover with a hole equipped with a vacuum valve for pumping out the gas phase, and an inlet for introducing a sample located at the base of the chamber, characterized in that the disintegrator is equipped with a system making a sample, which is a technological frame, between the upper and lower bases of which a removable receiving vessel is installed, the upper base of the frame is equipped with soy insignia with the base of the degassing chamber and the hole mating with the inlet of the chamber, and the lower base of the frame with a piston with a threaded thread mating with a thread in the technological frame, mounted with the possibility of movement in the receiving vessel, made in the form of a cylinder equipped with a removable vacuum liner, this base of the chamber is made with the possibility of rigid connection with the technological frame, one of the ends of the cylinder is equipped with an external annular limiter and an internal technological tide, and as chopper mounted metal balls. 2. The vacuum disintegrator of samples of bottom sediments and soils according to claim 1, characterized in that the second end of the cylinder is pointed. 3. The vacuum disintegrator of samples of bottom sediments and soil according to claim 1, characterized in that the connection of the chamber and the cover is made screw. 4. The vacuum disintegrator of samples of bottom sediments and soils according to claim 1, characterized in that the connection of the chamber and the cover is threaded.

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