RU2244282C2 - Hydraulic-controlled high resolution stratification water sampler - Google Patents

Abstract

FIELD: hydrology; hydrobiology.

SUBSTANCE: device for simultaneous sampling of water samples taken from layers of water laying close to each other, has set of cylinders with pistons disposed onto carrying frame. End parts of all cylinders are hermetically tied with multiplier, which is connected with pump by means of hose pipe. Front edges of all cylinders are provided with beaks having entrance holes for taking water samples. Pistons moves inside cylinders due to hydraulic tie-rod. Space inside hose-pipe, multiplier and end parts of all cylinders is filled with water to avoid corrosion.

EFFECT: improved reliability of efficiency of operation; better protection corrosion.

Description

The invention relates to the field of hydrology, hydrobiology, oceanology, hydrochemistry, ecology of reservoirs, aquatic microbiology and other areas related to the need to take water samples from certain depths. The device is intended for sampling water in stratified bodies of water, where layers appear in the water column between which chemical and microbiological parameters differ significantly at a distance of several centimeters in depth.

There are designs for water sampling, the main element of which is a series of horizontally located cylinders with pistons located inside them, mounted one above the other on a supporting frame. The piston stroke of the cylinders is controlled either by mechanical traction carried out by the springs (1) or pneumatically by means of air pumped out by a pump through a hose leading to the rear parts of the cylinders (2).

The device (1) is an analogue of the device we are proposing and is a bathometer including sample intakes made in the form of hollow sample cylinders mounted on a rod, and each sample inlet cylinder is equipped with a spring-loaded rod with a piston and is mounted for movement in a horizontal plane, and each sealing mechanism made in the form of a rigidly fixed on the outer surface of the cylinder slats with a groove, a slider installed in the groove with the possibility of free movement, and a spring-loaded a lever with a lid pivotally mounted in the slide, the arm being formed with a projection which can interact with the end surface of the rail (1).

However, this design contains a very large number of parts, which increases the likelihood of malfunctions due to wear of the springs, inaccurate fixing, failure of the covers, etc. The practice of working with triggers shows that they do not always work and working with them requires special experience, which is gained in the process of repeated unsuccessful attempts to take samples.

The disadvantage of this design is that at the time of taking a water sample there is a disturbance of the sampled fluid due to the rapid movement of the cylinders along the rods. This violates the validity of the samples.

Another disadvantage of this device is that the cylinders cannot be placed close to each other due to the presence on the outer surface of the parts of the sealing mechanism. Therefore, the distance between the samplers limits the resolution of the bathometer in cases where simultaneous sampling is required over a small interval (several centimeters) in depth.

The closest analogue of the claimed device is the device (2). In it, the main element is also a series of horizontally arranged cylinders with pistons (“syringes”) located inside them, mounted one above the other on a supporting frame. The tail parts of all cylinders are hermetically connected to a multiplier connected by a hose to the pump, and the front ends of all cylinders are equipped with nozzles with inlets for sampling water. The piston stroke is controlled by air pumped out by a pump through a hose leading to the rear parts of the cylinders (2).

In our opinion, the disadvantage of the described pneumatic control design is that it will not work reliably at great depths (more than 10 meters) due to the compressibility of the air. The use of an incompressible, rigid hose is undesirable due to the inconvenience of its location on the boat. In addition, under the pressure of water during immersion, the pistons of the cylinders can spontaneously retract, and water will begin to flow into the cylinder before the sampler is lowered to a predetermined depth. This will occur even when the upper end of the hose is blocked (for example, by a pump valve), since the air in the hose will be compressed under the pressure of the piston. Thus, the described construction works well only at shallow depths, for example, when studying the surface layers of the water column, while it is unsuitable for work in deeper layers of water bodies.

The technical result of the claimed device is the improvement of the “syringe” scheme and the elimination of deficiencies that prevent water sampling from various depths of water bodies with an interval of several centimeters in depth for the subsequent analysis of thin-layer inhomogeneities of chemical and microbiological characteristics in the studied water body. The technical result is achieved due to the fact that a device is used that contains a set of cylinders horizontally arranged on a supporting frame with pistons, the movement of which is carried out by means of hydraulic traction, which combines the tail parts of all cylinders; the tail parts of all cylinders hermetically connected to the multiplier are connected by a hose to the pump, the front ends of all cylinders are equipped with nozzles with inlets for sampling water, and the space inside the hose, multiplier and tail parts of all cylinders is filled with pure water or an alcohol solution.

In the study of water bodies, it is often required to study the chemical composition of water and the composition of microorganisms that inhabit this body of water. These indicators are not uniform in depth, and therefore there is a need to take water samples for analysis from different depths. As a rule, a device called a bathometer is used to take water samples from a given depth. In most reservoirs, the accuracy of sampling with an ordinary bathometer is about 1 meter in depth and is quite sufficient. But there are so-called stratified lakes in which, at a certain time of the year (or year-round), starting from a certain depth, there is no vertical mixing of water layers, and layers appear in the water column between which chemical and microbiological parameters very much differ already at a distance of several centimeters in depth. Our device was developed for sampling from such stratified lakes.

The basis of the invention is the above-described system of a series of cylinders mounted on a supporting frame (figure 1). The essence of the invention lies in the fact that a hydraulic rod is used to control the stroke of the pistons. The hose and the rear parts of the cylinders are combined through a multiplier into a single space filled with a working fluid, which is the main working fluid that moves the pistons in both directions. As the working fluid, pure tap or distilled water can be used to avoid corrosion of metal parts and increased wear of rubber gaskets and pistons. In addition, a 40-50% aqueous solution of ethyl alcohol can be used as a working fluid, since this allows the device to be operated and stored in winter at low temperatures and to prevent the internal space of the cylinders, multiplier and hose from overgrowing with microalgae and bacteria. Any suitable pump can be used to pump fluid through the hose. We have successfully used a large plastic medical syringe with a volume of 150 ml (Janet syringe) as a hand pump.

Device description

To solve the tasks we have mounted the following device, a diagram of which is shown in figure 1. The device consists of a supporting frame 1, on which are mounted horizontally one above the other cylinders 2. The number of cylinders can be arbitrary at the discretion of the researcher. The pistons of the cylinders 6 have shortened shanks 9, which serve only to prevent distortion of the piston during movement. The rear ends of the cylinders are hermetically connected to the multiplier 3, which in turn is hermetically connected to the hose 4. The space inside the hose, the multiplier and the rear parts of all cylinders to the pistons is filled with working fluid 7 and is a single container. The front ends of the cylinders are equipped with nozzles with inlet openings 10, through which water samples 8 pass from the reservoir into the cylinders.

Before sampling through the hose 4 with a pump attached to the free end of the hose (not shown), the working fluid is pumped into the device 7. In this case, the pistons due to hydraulic pressure move forward, towards the inlet holes 10. When all the pistons reach the stop, the device ready to take water samples from the reservoir.

Using a cable 5, the device is lowered from the vessel to the desired depth. In this case, the hose 4 extends along the cable, its upper end is connected to the pump and is located on the vessel.

After the device is brought to the sampling point, using the same (or another) pump, the working fluid 7 is pumped through a hose 4 into a separate container. Due to hydraulic pressure, the pistons begin to move in the opposite direction, while water flows from the reservoir through the holes 10 in the cylinder tank. After all the pistons are fully retracted, sampling is completed, the device is lifted aboard.

After sampling, the necessary operation is carried out - the selected water samples are removed from the cylinders. This operation is carried out in our design by pumping the working fluid 7 back into the hydraulic system using the same (or another) pump. It should be noted that a prerequisite for normal operation with such a design is the ability to extract samples from a cylinder of the researcher's choice, so that other cylinders remain filled with selected samples. In our design, this is as follows. After removing the device from the water, the inlets 10 of all cylinders are closed with rubber plugs (not shown), thereby preventing gas exchange of the selected water samples with the atmosphere. To take a water sample from the desired cylinder, open the plug on this cylinder and pump the working fluid with a pump through the hose, while the piston will only move on the desired cylinder, and the sample will pour out of the hole. Since the remaining cylinders are closed, their pistons remain stationary. To extract the sample from the next cylinder, open the corresponding plug. After extracting all the samples, the pistons will be in the starting position, and the hydraulic system will be filled with water to the maximum volume, i.e. the device is ready for the next sampling.

Numerous tests showed that contrary to expectations, the force for retracting several pistons (a series of 20 syringes was tested in our sample, Fig. 2) was spontaneously distributed in such a way that no more than two pistons moved at the same time, and most often only one. When the piston has completely passed the working distance, i.e. a sample was taken from one horizon, the next began to move, etc., and the sequence of the cylinders is always unpredictable and is determined by the existing small differences in the friction force, diameters of the hydraulic system, etc. Obviously, this does not affect the quality of sampling.

The positive point here is that to retract all the cylinders, the force required is the same as to retract one cylinder, only the sampling time increases.

Our design option consisted of 20 cylinders with a volume of 150 ml each (Fig. 2), the same cylinder was used as a hand pump. At the same time, sampling in the field took about 10 minutes.

The sample we made was successfully used during the summer field season of 2002 when investigating Lake Shira (Khakassia) (Fig. 2), where samples were taken from depths of 14-17 m. In this case, the distance between the cylinder nozzles and, consequently, the depth interval between samples amounted to 5 cm. For all the time the device was not a single failure was recorded.

This design has undoubted advantages in comparison with existing samples. Firstly, it allows you to take samples from almost any depth, since water, like any liquid, is incompressible. Due to this, the water in the hose is not compressed during pumping, therefore, there is no need to use a rigid hose. When immersed, the pressure of the water column in the hose is always equal to the ambient water pressure at the appropriate depth, so there is no danger of spontaneous retraction of the pistons due to external pressure, as this can happen in a pneumatic system.

Another advantage of the hydraulic system is that the volume of water pumped out of the hose exactly corresponds to the volume of samples taken. This feature helps the researcher on board the ship to determine whether all the cylinders were filled with water samples to the maximum possible volume by the amount of pumped working fluid.

This design contains a small number of parts, which increases the reliability of the device. Using clean water prevents corrosion of metal parts and reduces wear on rubber gaskets and pistons. In addition, when using a 40-50% aqueous solution of ethyl alcohol as a working fluid, it is possible to operate and store the device in winter at low temperatures. Another advantage of using an alcohol solution is that the internal space of the cylinders, multiplier and hose is prevented from overgrowing with microalgae and bacteria.

To designate such a device in Russian there is no corresponding term. Therefore, we propose the name “stratification bathometer”, since a bathometer in domestic hydrobiology is a device for sampling water from the required depth, and the word “stratification” reflects its main purpose. The term “thin layer water sampler” has already been established in English.

Literature

1. SU 981854 A, cl. G 01 N 1/10, published. 12/15/1982, 4s.

2. Alan L. Baker, Kathleen Kromer Baker and Peter Tyler. (1985) A family of pneumatically-operated thin layer samplers for replicate sampling of heterogeneous water columns. Hydrobiologia 122: 207-211.

Claims (1)

A device for simultaneous sampling of water, differing by a small interval in depth, containing a set of cylinders horizontally located on the supporting frame with pistons, the tail parts of all cylinders are hermetically connected to a multiplier connected by a hose to the pump, and the front ends of all cylinders are equipped with nozzles with inlets for water sampling, characterized in that the movement of the pistons in the cylinders is carried out by means of hydraulic traction, the space inside the hose, multiplier and tail parts of all cylinders ndrov to pistons in them is filled with clean water to remove corrosion.

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