SU31673A1 - Fluid sampling device - Google Patents

Description

Until now, in the practice of soil science and hydrology, as well as in other areas where we have to deal with the need to sample liquids from various predetermined depths, we usually resorted to simple pipettes. Sampling the latter is quite difficult, since it requires great care from the side of the worker. Especially sharply it appeared during the mass production of works. Recently, a large distribution in soil science has adopted the method of mechanical analysis of soils and soils, where a quantitative account of soil suspensions is carried out, based on sampling at a certain time and from various depths certain volumes of suspensions. In order to simplify this work, as well as to enable the analyst in a relatively short period of time, not to get tired of taking a large number of samples, a device is proposed that takes fluid samples from various predetermined depths, and from the working side only turning in proper side of the faucet, resulting in the required volume of fluid.,

In FIG. 1 shows a general view of a device mounted on a tripod; FIG. 2 is a side view of the tripod; 3-

(347)

View from above; FIG. 4-part instrument; FIG. 5-detail modification of the device; FIG. b-detailed view of the two-way crane; FIG. 7 double bole; FIG. eight,. 8 cross-sections of it, showing the relative position of the moves.

A liquid sampling device consists of a pipette, and a vessel AB: The lower reservoir B of this vessel ends with an exit tube C with a tap K; the upper reservoir A passes through a glass O drain into it; the end of which is located in the place of lintel of both tanks A and 5 in such a way that when the lower tank B is filled with liquid, the latter is placed in it up to the lower end of tube O in a definitely measured amount (for example, 20 cm, 30 cm - etc.). The upper part of the tank A is withdrawn into the tube I, which communicates with an aspirator serving to suck the liquid sample into the vessel AB. A two-blond cock / / (Fig. 4) is connected to the pipette with the help of rubber hoses, and its lower rus is exactly the same as the upper one. Each Russian crane L has four turns, of which f, 2, (figs. 7 and 8, 8) are located in the same plane of the crane section and, being at a distance of 90 ° from each other, are connected in pairs for 1 s 2, 2 with 3 coal stroke ab (Fig. S), the stroke is somewhat shifted towards the previous three moves and can be connected only with stroke 2 using the forward stroke ed drilled in the inside body of the crane,

For actuating the device, the individual strokes of the cranes are connected

parts of the latter in the following sequence: stroke / directly connected by a rubber hose to the pipette tube L, which is prepared separately from the latter and the desired length, with a sealed lower end, where a number of horizontal orifices of the required diameter are made, which makes it possible to take a suspension From the horizontal layer of fluid where the pipette is loaded. Stroke 7 is connected to an aspirator, stroke 2 is connected to a tubular tube O of the lower reservoir B, and 2- to tube G of the upper reservoir A. Stroke 3 has a rubber hose and serves to drain, and stroke 3 connects vessel AB with air. Stroke 4 is connected with a vessel with distilled water, and 4 with air.

The operation with the help of the proposed device is performed as follows. The pipette tube L is immersed in the test liquid and at the moment the N valve is positioned so that none of its strokes is connected to the other, in order to prevent the liquid from entering the tube until the moment of sampling. The next turn of the crane N connects the moves / s 2 and 7 with 2, and at the same time the aspirator starts to act, which sucks the air out of the vessel AB, by virtue of which the pipette L through the knee of the tube O first flows into the lower reservoir 5, and then, as it is filled, and into the upper A. Once the liquid rises slightly above the lintel of both tanks, the valve is given a new position, connecting strokes 2 with 3 and 2 with 3, due to which the air entering the vessel AB through stroke 5 causes

where, in the last to the atmospheric, the opened bypass: 5, drain the least pipe, 0 ,,, .. as by,: siphon,: discharge, all — from the current to the liquid. above

4iQHi a-Tp, y6, KH.Oj TaknM: way, liquid

will remain in the AS vessel only in quantity,

equal to the volume of the lower reservoir B. Then open the valve / C of the discharge tube C and pour the liquid into the delivered dish. In order to clean the walls of the lower tank B, the crane N is turned to the third position, which connects the passages 4 to 2 meters 4 to 2, i.e. Distilled water flows into reservoir B through passage 4, washing its walls, and through passage, air. This ends the sampling operation, which, according to the author's experiments and depending on the force of the aspirator, takes 10-15 seconds. In this way, it is meant to ensure that the excess suspension (or liquid in general) does not flow back into the vessel and do not stir up the suspension, but are discharged through the drain and thus it would be possible to take successively any number of samples from the same vessel. mixing there, which is important, in particular, when taking samples of suspensions in the production of mechanical analysis of soil or soil,

In the modified instrument shown in FIG. 5, the vessel AB is connected to the pipette and to the vessel with distilled water with a tee O. At the exit from tank A, one branch g of the tee is connected to the pipette L, and the other to the vessel with distilled water. The upper tube of reservoir A is connected by rubber hoses to tap M (Fig. 5), one stroke of which is connected to the aspirator and the other one remains open for connection to air. In this case, it is possible to attach any number of pipettes to one tap (depending on the force of the aspirator) using tees and simultaneously take a series of samples or from different depths of one vessel or from different vessels. The method of operation is the same, but in this case, the excess liquid that entered the upper tank A of the vessel AB is not drained by a special drain, as was the case in the first embodiment, but goes back to the vessel, although it is possible to avoid both of them and the church. , h | 1c faucet; P about with le set a ,, liquid, not .. c a. Vrz down, and about razrm ,. to go doedi,. between co;; t (and it is necessary to take out the pi from the vessel, from the ffpoSa

and, substituting the Z cup at the end of the tube, switch the tap to the air, after which all the excess will be drained outside the vessel from where the sample was taken, and the liquid in the latter will not be stirred up.

The instrument stand (Figs. 2 and 3) at its base has a metal disk, in the center of which a cylindrical floor tube is fixed with divisions in millimeters. The disk P is resting on three ball wheels located at the corners of the triangle inscribed into the disk; on the outer side of each moving ball (to the periphery), one set screw q is placed along the latter; this allows the base of the tripod to be brought to a horizontal position along the levels placed on the disk P. In the lower part of the cylindrical hollow tube R there is a worm gear box s, - v. A sprocket is mounted on one axis with a worm gear, and it is smoothing with chain links Z. A cylindrical tube R is fitted with a coupling, in the upper part of which the outer diameter is ground, and a second coupling with two soldered plates is mounted on it. At the upper end of the cylindrical column, a single gear with spikes for chain z is fixed. When rotating the knob t of the worm gear and the two mufgs mentioned above with the help of a chain gear, they can smoothly rise or fall along the cylindrical rack. A surface coupling in its wall has a screw hole through which a screw passes, securing it in the desired position. Two wings with identical structural parts are attached to the upper clutch. These wings serve to hold the device; two sockets are fixed at the top and bottom for inserting a vessel into them, the lower nest being stationary and the upper one moving in the vertical direction. Closer to the outer edge of the wing are two plates that have

a midline cut-out through which two screws securing them pass; at the outer end of the plate there are clips, with the help of which the pipette L is fixed in the vertical position. Finally, a table for cups is attached to the lower part of the wing, into which the samples are poured.

During operation, the tripod can move between two rows of set vessels, from which samples are taken, moving forward and taking successively the first samples from the right and left side, or, remaining stationary in place, can take samples from vessels placed in a circle, in the center of which he stands; however, only the top clutch with the wings is moved.

The subject matter of the invention.

Claims (4)

1. A device for taking and sampling liquids using a pipette, characterized in that the pipette L is connected to the sample vessel A If, connected through a tube G to an aspirator that serves to suck the liquid sample into the vessel AB. 2. The form of the apparatus according to claim 1, characterized in that the vessel AB is provided with a drain pipe O. which serves to remove excess sample from the vessel. 3. The form of the device according to p. 1, 2, characterized in that to connect the vessel AB with a pipette and an aspirator or a drain tube and air, or with air and a vessel with distilled water, one two-meter tap L is used, each of which has four turns. 4. A device change according to claim 3, characterized in that the choo vessel is connected to the pipette and the vessel with distilled water with a tee O, and to attach the vessel AB to; Aspirator and atmospheric air is a two-way valve. the certificate of P.F. to the author Martynov No. 8164 3 in author's certificate of Ya. F. Map tynova No. 31-73