RU167655U1 - LIQUID SAMPLE - Google Patents

Abstract

The utility model relates to devices for sampling liquid from predetermined depths and can be used for laboratory research and for environmental monitoring. The liquid sampler contains a round casing with a through cavity, which has a receiving hole on one side and an outlet on the other. On the outlet side, a cable is attached to the housing for measuring the depth of immersion. At the same time, a receiving valve is located in the inlet opening having an inlet conical saddle and an outlet conical saddle. An exhaust valve having an inlet conical surface and an outlet conical surface is disposed in the outlet. The outlet cone seat of the inlet valve and the inlet cone surface of the outlet valve form a transport cavity. A front ball-float is mounted in the inlet, connected by an axis to the rear ball-float installed in the outlet. In the transport cavity, a central ball-float is sealed on the axis. The central ball-float has the ability to move along the axis. From the side of the receiving hole, a lifting cable is attached to the front ball-float. The front ball-float has the ability to overlap the receiving valve. The central ball-float has the ability to alternately overlap the intake valve or exhaust valve. The rear ball-float has the ability to block the exhaust valve. The utility model made it possible to obtain a technical result, namely, it provided a sampling of a liquid from a given depth. f-ly and 2 ill.

Description

The utility model relates to devices for sampling liquid from predetermined depths and can be used for laboratory research and for environmental monitoring.

It is known "Device for sampling liquids" according to the patent of the Russian Federation for invention No. 2315277, containing a hollow chamber, a valve for fluid intake and a cable for lowering the chamber, while the poppet type check valve is located in the lower part of the chamber, and the upper part of the chamber is connected through a flexible reinforced a hose in series with a manometer, gas meter, three-way valve and a cylinder with compressed inert gas.

The disadvantages of the known device according to the patent of the Russian Federation for the invention No. 2315277 are:

- the complexity of the design, due to the use for operation of the device of a compressed inert gas coming from a cylinder;

- the filling of the chamber with liquid at a given depth is judged by the readings of the gas meter, while the volume of the liquid sample can vary over a wide range.

The well-known "Sampler for determining the thickness of the oil layer above water" according to the patent of the Russian Federation for invention No. 2452933, adopted as the closest analogue, containing a thin-walled vertical housing with a handle in the upper part and a tapered valve seat in the lower part, a ball for overlapping the saddle, while the ball suspended on the fishing line to the handle with the provision of two positions of the ball relative to the saddle, and at the lower point of attachment of the fishing line to the handle, the ball freely lies on the saddle and overlaps it, and at the upper point of attachment of the ball is raised above the saddle.

The disadvantage of the known "Sampler for determining the thickness of the oil layer above water" according to the patent of the Russian Federation for invention No. 2452933, are:

- the inconvenience of operation of the device, since the opening and closing of the valve is carried out by moving the ball suspended on the fishing line;

- there is no possibility of taking fluid samples from a given depth.

The claimed utility model is tasked with sampling a liquid from a given depth.

The problem in the inventive utility model is solved due to the fact that the liquid sampler contains a round body with a through cavity, which has a receiving hole on the one hand and an outlet on the one hand, and a cable for measuring the depth of immersion is attached to the body on the side of the outlet wherein, in the inlet there is a inlet valve having an inlet cone seat and an outlet cone saddle, in the outlet there is an outlet valve having an inlet the taper surface and the exit conical surface, the outlet conical saddle of the intake valve and the inlet conical surface of the exhaust valve form a transport cavity, a front ball-float is installed in the inlet, connected by an axis to the rear ball-float installed in the outlet, in a transport cavity hermetically on the axis a central ball-float is installed, the central ball-float has the ability to move along the axis, from the receiving hole to the front ball-float captive a lifting cable, the front ball-float has the ability to overlap the intake valve, the central ball-float has the ability to alternately overlap the intake valve or exhaust valve, the rear ball-float has the ability to overlap the exhaust valve.

The claimed utility model differs from the well-known “Sampler for determining the thickness of the oil layer above water” according to the RF patent for invention No. 2452933 in that there is a receiving valve in the inlet having an inlet cone saddle and an outlet cone saddle, in the outlet there is an outlet valve having the inlet conical surface and the outlet conical surface, the outlet conical saddle of the intake valve and the inlet conical surface of the exhaust valve form a transport cavity in the receiving The front ball-float is installed in the hole, connected by an axis to the rear ball-float installed in the outlet, the central ball-float is sealed on the axis in the transport cavity, the central ball-float is able to move along the axis, from the receiving hole to the front ball - a lifting cable is attached to the float, the front ball-float has the ability to overlap the intake valve, the central ball-float has the ability to alternately overlap the intake valve or exhaust valve Ana, the rear ball-float has the ability to block the exhaust valve.

The indicated difference made it possible to obtain a technical result, namely, it ensured sampling of a liquid from a given depth.

In FIG. 1 shows a longitudinal section of a sampler, showing the position of its elements when immersed.

In FIG. 2 shows a longitudinal section through a sampler, showing the position of its elements when lifting the sample.

The liquid sampler (Fig. 1, 2) contains a round 1 cross-sectional body 1 with a through cavity 2, which has a receiving hole 3 on the one hand and an outlet 4 on the other hand, and a cable 5 for measuring is attached to the body 1 from the outlet 4 depth of immersion, while in the inlet 3 there is a receiving valve 6 having an inlet cone saddle 7 and an outlet cone saddle 8, in the outlet 4 there is an outlet valve 9 having an inlet conical surface 10 and an outlet conical surface 11, the outlet conical saddle 8 of the intake valve 6 and the inlet conical surface 10 of the exhaust valve 9 form a transport cavity 12, a front ball-float 13 is mounted in the receiving hole 3, connected by an axis 14 to the rear ball-float 15 installed in the outlet 4, in of the transport cavity 12, the central ball-float 16 is sealed on the axis 14, the central ball-float 16 has the ability to move along the axis 14, from the side of the receiving hole 3 to the front ball-float 13 is attached a lifting cable 17, per dny ball-float 13 has the possibility of overlapping receiving valve 6, the central ball-float 16 has the ability to alternately overlap receiving valve 6 or exhaust valve 9, a rear ball-float 15 has the possibility of overlap of the exhaust valve 9.

The fluid sampler operates as follows. The lifting cable 17 is lowered into the liquid, so that it has no tension (Fig. 1). The housing 1 under its own weight is immersed in the liquid in an upright position, holding the cable 5 for measuring the depth of immersion attached to the housing 1 from the side of the outlet 4. The intake hole 3 is located at the bottom, the outlet 4 at the top. The immersion depth of the housing 1 is determined by the length of the cable 5 for measuring the immersion depth. When immersed connected by an axis 14, the front ball-float 13 in the inlet 3 and the rear ball-float 15 in the outlet 4 float. The front ball-float 13, pressing against the inlet cone seat 7, closes the inlet valve 6. The back ball-float 15, which comes out of contact with the outlet conical surface 11, opens the outlet valve 9. Liquid through the open outlet valve 9 fills the transport cavity 12, the central ball-float 16 floats up, moving upward along the axis 14. The central ball-float 16 is hermetically, for example, through a rubber O-ring, mounted on the axis 14. The central ball-float 16, interacting with the input conical surface 10, closes the exhaust valve 9. The transport cavity 12 is isolated on one side by a closed receiving valve 6, and on the other hand by a closed exhaust valve 9. The housing 1 is immersed to a predetermined depth, which is controlled along the length of the cable 5 for measuring the depth of immersion. The immersion is stopped and the lifting cable 17 is selected. Under the tension of the lifting cable 17, the housing 1 is rotated 180 °, while the front ball-float 13 moves away from the inlet cone seat 7, opening the receiving valve 6 (Fig. 2). The front ball-float 13 and the rear ball-float 15 connected to it by an axis 14 float. The liquid from a given depth begins to flow into the transport cavity 12. The central ball-float 16 floats, moving along the axis 14, moves away from the inlet conical surface 10 and opens the exhaust valve 9. Through the open intake valve 6 and the open exhaust valve 9 through the through cavity 2 passes fluid at a given depth. From the transport cavity 12, the liquid that has got into it when immersed is washed out. Floating up the central ball-float 16 interacts with the outlet saddle 8 and closes the inlet valve 6. Also, floating up the back ball-float 15 interacts with the outlet conical surface 11 and closes the outlet valve 9. The transport cavity 12, which contains a sample of liquid from a given depth, is isolated from the surrounding fluid with a closed receiving valve 6 and a closed exhaust valve 9. The housing 1 for the lifting cable 17 is removed from the liquid. When the tension of the lifting cable 17 is weakened, the rear ball-float 15 moves away from the output conical surface 11, the exhaust valve 9 opens, and a sample of liquid from a given depth from the transport cavity 12 is discharged into laboratory equipment for analysis.

The utility model made it possible to obtain a technical result, namely, it provided a liquid sampling from a given depth.

Claims (1)

 A liquid sampler comprising a body round in cross section with a through cavity, which has a receiving hole on one side and an outlet hole on the other side, a cable for measuring the depth of immersion is attached to the body on the side of the outlet hole, characterized in that a receiving valve is located in the receiving hole having an inlet cone saddle and an outlet cone saddle, an outlet valve is located in the outlet, having an inlet cone surface and an outlet conical surface, an outlet the conical saddle of the receiving valve and the inlet cone surface of the exhaust valve form a transport cavity, a front ball-float is installed in the receiving hole, connected by an axis to the rear ball-float installed in the outlet, the central ball-float is sealed on the axis, the central ball the ball-float has the ability to move along the axis, from the side of the receiving hole to the front ball-float is attached a lifting cable, the front ball-float has the ability receiving valve overlap, central ball-float has the ability to alternately overlap receiving valve or an exhaust valve, a rear ball-float has the possibility of overlap of the exhaust valve.