RU102112U1 - PROBE FOR SAMPLING WATER FROM BOTTOM SEDIMENTS - Google Patents

Abstract

 1. A probe for sampling water from bottom sediments, including a control unit connected via a cable to an airtight container containing a system of at least two containers connected in parallel with hoses for accumulating water samples and a sampling tube, one end of which is connected through an electromagnetic valve with a system of containers, and the second end is made with openings for the entry of pore water and is equipped with a filter, while the containers for pore water are made in the form of syringes whose piston rods are blocked Inonii clamps so as to ensure their unlocking and filling syringes with water depending on the horizon immersion precipitation in the sampling tube, and the probe is equipped with a mechanism for immersing the sampling tube and a system of tracking the depth of its immersion in the precipitation. ! 2. The probe according to claim 1, characterized in that the immersion mechanism is made in the form of a shock-vibrator device. ! 3. The probe according to claim 1, characterized in that the immersion mechanism is located outside the container on the lid or inside the container on its base. ! 4. The probe according to claim 1, characterized in that the sampling tube is provided on the outside with a marking. ! 5. The probe according to claim 4, characterized in that the tracking system for the depth of immersion of the sampling tube in the precipitation is a television or video camera with a light attached to the probe container so that the marking of the sampling tube is in the field of view of the camera. ! 6. The probe according to claim 1, characterized in that the tracking system of the depth of immersion of the sampling tube in the precipitation is made in the form of a pressure sensor. ! 7. The probe according to claim 1, characterized in that the container

Description

The utility model relates to the field of oceanology, hydrochemistry, geochemistry and ecology of water bodies, and in particular to devices for sampling water contained in bottom sediments of water areas (pore water), and can be used to obtain primary material for the analysis of the chemical and microbiological composition of water, as well as to study the interaction of water masses with bottom sediments and to study the chemical reactions occurring in sediments.

Unlike a large number of different devices and devices for sampling bottom sediments or water from different horizons and depths, the number of devices for taking in situ water samples from bottom sediments is limited.

It is known to use devices for sampling water from different horizons of bottom sediments, which are tubes with devices for holding a tube that penetrates during vertical immersion in bottom sediments (AS USSR No. 582473, IPC G01N 11/10). As such devices, a special valve is installed at the base of the tube, for example, made of thin elastic metal plates fixed fan-like around the circumference inside the tube. Vertical immersion of the tube is carried out either by free fall, or using a pneumatic pusher. After raising the tube to the surface of the reservoir, samples of the bottom soil are removed from it, and subsequent sampling of pore water from the samples obtained is carried out in laboratory conditions, for example, using evacuated tubes or syringes, each of which draws fluid from a specific section of the bottom soil sample (http: / /www.eijkelkamp.com/Products/Cataloguesection/tabid/76/CategoryID/20/List/1/Level/a/ProductID/102/Default.aspx).

A device for pumping water directly (in situ) from bottom sediments from one or more horizons (VZ US No. 2006090894, IPC ЕВВ 49/08). The device consists of a chamber equipped with a variety of miniature cylindrical samplers vertically distributed with the possibility of horizontal movement relative to precipitation. Samplers are equipped with hydrophilic microporous polymer inserts with an internal supporting wire base made of stainless steel or plastic and connected via PVC tubes to a suction device made in the form of a syringe or peristaltic pump. However, due to its miniature size, this device allows one to study with a high resolution only a very small depth layer of bottom sediments.

Known sampler PushPoint (http://cluin.org/programs/21m2/sediment/#refs#refs), consisting of a cylindrical tube equipped with a shielding plate, which is superimposed on the surface of the sediment at the sampling point to prevent water from seeping into the sampler sedimentation of the water layer during the sampling process. The sampler is equipped with a protective rod, which is placed in the tube while immersing it in precipitation to give rigidity and prevent deformation of both the tube itself and the shielding plate. The cylindrical sampling tube is immersed in the sediment from the surface of the water so that the opposite end of the tube being immersed rises above the surface of the water. After immersing the sampling tube into the sediments to the required depth, the protective rod is removed from the tube and the open end of the tube is connected via a hose to a peristaltic pump or syringe, with the help of which pore water is taken into vessels located, for example, in the boat.

The BAT ™ sampler pore water sampling system (http://cluin.org/programs/21m2/sediment/#refs#refs) is known, consisting of a device for collecting pore water and a special tool for delivering collected water to the surface for subsequent analysis. A device for collecting pore water consists of a tip and a casing, the top of which is closed using a disk containing a flexible valve. Pore water enters the casing through the tip, if it is made of porous high-density polyethylene, if a vacuum is created inside the casing. Or the lower part of the casing is equipped with a special insert, which is a filter made of porous polyethylene, protected by a cylindrical metal shell, and a metal tip. When the tip penetrates the precipitation to the required depth, the protective shell shifts, opening the filter through which pore water fills the casing. The tip in this case serves to penetrate dense precipitation. The selected pore water is delivered to the surface for subsequent analysis by a special tool containing a vacuum bubble, equipped with a stopper with a valve and a double-edged needle, which drops to the valve installed on the casing and penetrates simultaneously through the casing valve and the bubble valve, allowing water to flow into the evacuated bubble for subsequent analysis.

Also known is a multilevel pore water sampler for permeable sediments (Jonathan B. Martin L, Kevin M. Hartl, D. Reide Corbett, Peter W. Swarzenski and Jaye E. Cable "A multi-level pore-water sampler for permeable sediments", Journal of sedimentary research, vol.73, no.1, January, 2003, p.128-132), consisting of a polyvinyl chloride pipe with several inlets for sampling pore water located in a spiral line around the pipe at certain distances from each other. To increase the area of selection of pore water from the outside, the pipe is equipped with grooves connected to the holes. The holes and grooves are covered with a polypropylene mesh, which is pressed against the pipe with a plate with windows. The sampling holes are provided with thin polyvinyl chloride tubes, the upper ends of which are led out through the upper hole of the main pipe and connected to the fittings of the hydraulic connector, and the lower ends are glued to the outer surface of the carrier pipe near the holes. A multi-level sampler is immersed in precipitation using a pneumatic pusher. Samples of pore water from different horizons of bottom sediments are pumped to the surface of the reservoir at the same time using peristaltic pumps, each of which is connected to the corresponding tube. Further preparation of samples for analysis is carried out according to standard methods.

However, all of the above constructions of devices for sampling pore water turn out to be functional only in shallow water areas for two reasons:

- for immersion of these devices in precipitation, a force action from the water surface or the work of a diver is necessary;

- obtaining samples of pore water for subsequent analysis is carried out using thin hoses brought to the surface of the reservoir, using peristaltic pumps or using devices for vacuum suction installed on watercraft.

The closest analogue of the claimed device is a probe - Trident probe (p. US No. 7711489, IPC G01N 15/08). The probe is a platform equipped with tubes, the upper ends of which are mounted on the platform. The required sensors, for example, temperature, conductivity, oxygen content and others, are mounted in the lower end openings of the tubes. The end hole of one of the tubes is equipped with a filter through which pore water is pumped out and flows through the tubes into containers located in the container located on the surface of the reservoir. A pneumatic pusher is installed on top of the platform, which allows you to incorporate all the tubes into the investigated precipitation. To operate the pneumatic pusher, compressed air is supplied from the surface of the reservoir. The probe is controlled by a processor.

The depths of the water areas at which the Trident probe can be used are increased compared to the working depths of the above devices due to the possibility of remote control of the probe immersion process in sediments, however, these depths are still limited to several tens of meters, since the accumulation of pore water samples for subsequent analysis occurs on the surface of the reservoir, and with increasing depth of the reservoir, the time of the arrival of pore water on the surface increases so much that it exceeds the time interactions shafts investigated phenomena.

The objective of the utility model is to develop the design of the sampler, which allows to increase the depths of the water areas at which it is possible to take pore water samples in the in situ conditions, that is, directly from bottom sediments, increasing the efficiency and quality of samples taken by reducing losses during sampling and inflow of pore water from neighboring horizons, as well as reducing the time taken to obtain the sample.

The problem is solved by a probe for sampling water from bottom sediments, consisting of a control unit connected via a cable to an airtight container containing a system of at least two containers connected in parallel with hoses for accumulating water samples, and a sampling tube, one end of which is connected through an electromagnetic valve with a system of containers, and the second end is made with holes for the entry of pore water and is equipped with a filter, while the containers for pore water are made in the form of syringes, piston tubes whose currents are blocked by spring-loaded clamps in such a way as to ensure their unlocking and filling of the syringes, depending on the immersion horizon of the sampling tube in precipitation, and the probe is equipped with a mechanism for immersion of the sampling tube and a system for tracking the depth of its immersion in sediment.

The number of pairs of containers for collecting pore water samples is arbitrary, and is determined by the research task, the number of horizons from which samples should be taken and the required sample volume.

A system for tracking the depth of immersion of a sampling tube in precipitation can be implemented, for example, in the form of a television or video camera with an illuminator mounted on the probe container so that the markings applied previously to the side surface of the tube are in the field of view of the camera. If necessary, the chamber can also be used to select a sampling location for pore water. The tracking system can also be implemented as an appropriate pressure sensor.

The immersion mechanism of the sampling tube can be performed, for example, in the form of any shock-vibrator device, and can be located both outside the container on its lid and inside it on its base.

The container may additionally be equipped with sensors for temperature and / or conductivity and / or oxygen content.

In FIG. one of the possible schemes of the proposed probe is presented, where 1 is a sampling tube; 2 - hole for the entry of pore water; 3 - filter; 4 - the electromagnetic valve; 5 - a hose for connecting syringes; 6 - syringes, 7 - spring-loaded clamps, 8 - pressure sensor; 9 - stoppers of full travel of the syringe rods with limit switches, 10 - connector connecting the electrical components of the sealed container through a cable-cable 11 with a control unit (not shown in Fig.); 12 - body of a sealed container; 13 - immersion mechanism.

The probe works as follows.

The container 12 is lowered into the water until the bottom soil is touched by the sampling tube 1. The moment of contact is fixed either with a video camera (not shown in Fig.), Or if it is absent, it is determined by a sharp decrease in the cable tension 11.

The sampling tube 1 is deepened into precipitation to the required depth using the immersion mechanism 13, which is activated from the control unit of the control unit via a cable-cable 11. When pipe 1 reaches the first sampling horizon from the control unit, a signal is sent to open the solenoid valve 4 and water flows through the hose 5 into the sealed container to the syringes 6. The flow of pore water from the sediment into the syringes is ensured by reduced pressure in the sealed container with respect to the sampling point in the sediment thickness, which automatically occurs This is due to the fact that the container is sealed above the surface of the water before immersion. Pore water coming through the hose 5 presses on the pistons of the syringes 6 and through the rods this pressure is transmitted to the spring-loaded clamps 7. The force required to break the clamp 7, allowing the movement of the syringe rod and, therefore, to fill it with water, is pre-set experimentally so that for of each subsequent syringe, the magnitude of the force was greater than for the previous one. This achieves a certain sequence of filling syringes and the correspondence of each pair of syringes to a certain sampling depth. The sequential filling of at least two syringes on one horizon allows you to remove the remaining water from the previous horizon into the first syringe and thus increase the purity of the sample in the second on each horizon. The filling of each syringe is limited by stoppers 9, in which the rods abut during their movement during the filling process. The stoppers 9 are equipped with limit switches, due to which the syringe filling signals are sent to the control unit panel. Upon receipt, for example, of every second signal from the limit switches, the control unit generates an impulse to close the electromagnetic valve 4 and the sampling tube 1 is buried to take another sample to the next horizon by turning on the immersion mechanism 13.

Thus, the implementation of the inventive probe in the form of a single sealed container, equipped with both an immersion mechanism and a sampling tube and an original water sampling system, as well as the absence of long lines for delivering water samples to containers, allows to increase the depths of water areas where pore sampling is possible water in situ, to increase the efficiency and quality of samples taken by reducing losses during sampling and inflow of pore water from neighboring horizons, as well as significantly reduce time spent on sampling from great depths.

Claims (7)

1. A probe for sampling water from bottom sediments, including a control unit connected via a cable to an airtight container containing a system of at least two containers connected in parallel with hoses for accumulating water samples and a sampling tube, one end of which is connected through an electromagnetic valve with a system of containers, and the second end is made with openings for the entry of pore water and is equipped with a filter, while the containers for pore water are made in the form of syringes whose piston rods are blocked Inonii clamps so as to ensure their unlocking and filling syringes with water depending on the horizon immersion precipitation in the sampling tube, and the probe is equipped with a mechanism for immersing the sampling tube and a system of tracking the depth of its immersion in the precipitation. 2. The probe according to claim 1, characterized in that the immersion mechanism is made in the form of a shock-vibrator device. 3. The probe according to claim 1, characterized in that the immersion mechanism is located outside the container on the lid or inside the container on its base. 4. The probe according to claim 1, characterized in that the sampling tube is provided on the outside with a marking. 5. The probe according to claim 4, characterized in that the tracking system for the depth of immersion of the sampling tube in the precipitation is a television or video camera with a light attached to the probe container so that the marking of the sampling tube is in the field of view of the camera. 6. The probe according to claim 1, characterized in that the system for monitoring the depth of immersion of the sampling tube in precipitation is made in the form of a pressure sensor. 7. The probe according to claim 1, characterized in that the container is additionally equipped with sensors for temperature and / or conductivity and / or oxygen content.