SU1303705A1 - Installation for agent treatment of ejector needle filters - Google Patents

Abstract

The invention relates to the field of water supply, in particular to installations for the reagent treatment of ejector needle filters. The aim of the invention is to simplify the technology of the curing; bch-g: ...... ejector needle filters. The installation includes a source of compressed air, a waste pipe with a valve tap, a pressure gauge and a reagent tank communicated by a reagent line, equipped with a valve tap, with a filter and an air line with a source of compressed air. The installation is equipped with an additional reagent. capacity, and one of the reagent containers reagent line communicated with the annular space of the ejector needle filter, and the other - with its internal cavity. Each reagent tank is provided with a cylindrical perforated insert with upper and lower conical seats and a floating ball valve placed inside the insert, with the lower conical saddle in communication with the reagent line and the upper one with a waste pipeline. I zp f-ly, I ill. with (O (L with

Description

one

The invention relates to the operation of an ejector needle filter installation, in particular, to an installation for restoring the performance of an ejector needle filter with reagent methods.

The purpose of the invention is to simplify the processing technology of the ejector needle filters.

The drawing shows a schematic diagram of the proposed installation of reagent processing of ejector needle filters.

The installation includes a source of compressed air, for example, a high-pressure cylinder 1 with a valve 2 and a gearbox 3, two reagent tanks Ai 5 identical in their design, air lines 6 and 7, communicating tanks 4 with a ballast 1, and reagent lines 8 and 9 containing these containers, respectively, with the annular space 10 of the ejector needle filter and the internal cavity of its central column 11, filter 12 and filter zone 13. The annular space 10 and the remaining cavities of the needle filter are connected to each other by an ejector om 1 4.

Each container consists of a housing 15, an airtight cover 16, sealed at the bottom of the housing 15 of the lower cone seat 17, to the lower part of which a connecting nipple 18 with a valve is attached.

19, and to the top - a perforated insert inside the container

20 placed inside the insert of the floating ball valve 21, freely inserted into the upper part of the perforated insert of the upper cone sedp 22 attached to the relief pipe 23 with the valve 24 and the discharge nozzle 25 with the valve 26 and the pressure gauge 27.

The saddle 22 is assembled with the waste pipe 23 and the crane 24, the discharge nozzle 25 assembled with the crane 26 and the pressure gauge 27 are attached to the lid 16, and the saddle 22 assembled with the waste pipe 23 and the crane 24 is a removable flange assembly, hermetically sealing on the lid 16, the same applies to the lower seat 17 in the collection with the connecting pipe 18 and the valve 19, pack

It is similar to the bottom of the core 15 and Pus 15.

Thus, the installation is entirely located outside the ejector filters to be processed and, unlike devices that process wells on water, does not introduce any design changes or additions to the design of the needle filters.

When sampling groundwater from the reservoir using an ejector filter in the filter zone 13, hydrodynamic perturbation of the produced water occurs, which upsets the equilibrium state of the main chemical components of the ground water and causes clogging formations in the filter zone, on the filter 12, in the intertubular the space 10 of the needle filter and in the inner cavity of its central column 11.

When capturing groundwater of the bicarbonate type in the composition of clogging formations (50–80%) of iron compounds prevail.

Colmatting sediments partially fill the pore space around the filter, up to 10 mm from it, forming a weakly cemented casing around the filter, penetrate through the openings of filter 12 into the internal cavity, as well as into the annular space 10 and into the internal cavity of the central column 11 of the needle filter.

Due to clogging of the filter zone 13, filter 12 and increase

on the walls of the annular space 10 and the internal cavity of the central column 11 of ferrous and other closure joints, the ejector needle filter reduces productivity. Such an needle filter is disconnected from the rest of the water-reducing system and attached to the proposed installation in such a way that the reagent-tank 5 has the ability to

open valve 19 through the connecting pipe 18 and the reagent line 8 communicate with the intertubular space 10 of the needle filter, and the tank 4 with the internal cavity of the central column 11, filter 12 and filter zone 13. This completely eliminates the need to dismantle the ejector needle filter.

The device works as follows.

One of the reagent vessels, for example, 4, with the closed valve valve 19 and the removed upper cone seat 22, is filled with reagent 28, for example, sodium dithionite solution () of 10% concentration (which is slightly higher than the recommended 6-7% concentration) after which the seat 22 is sealed to the lid 16, valve valve 24 of the discharge pipe 23 of the reagent tank 4 is closed and valve valves 24 and 19 of the reagent tank 5 are opened, and the valve 26 of this tank is closed.

The reducer 3 is adjusted to the required pressure, for example, for ejector needle filters with a depth of 10 m. The EIN of the ejector, the pressure should be approximately 2-5 kgf / cm and for needle filters with a depth of 20 m for the ejector, 3-6 kgf / cm. Open the valve 2 of the compressed air source and the valve 26 of the reagent tank 4.

Under the pressure of compressed air, the reagent 28 through the reagent line 9 first enters the internal cavity of the central column 11, and then through the ejector 14 - into the filter 12, the filter zone 13 and the annular space 10 of the ejector needle filter. From here, through the reagent line 8, the reagent enters the reagent tank 5. The level of reagent 28 in the reagent tank 4 decreases in this case, and in the reagent tank 5 it grows. After the floating ball valve 21 of the tank 5 is loaded onto the upper cone seat 22, which will be indicated by a pressure gauge 27 by a pressure jump in this tank, the supply of compressed air to the tank 4 should be continued until the floating ball valve 21 sits on the lower cone seat 17, which will also be marked by a pressure jump on the pressure gauge 27, but already this capacity. Next, the valve 26 of the container 4 is closed using a valve 24 and the waste pipe 23 communicates the internal cavity of the container 4 with the atmosphere and on the contrary, the valve 24 of the container 5 is opened and the valve 26 is opened and compressed air is supplied through the reagent line 6. In this case, the reagent is

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The tubular space 10 of the injector needle needle filter through the ejector 14 enters the internal cavity of the central column 11, and from there along the reagent line 9 goes back to the tank. The pressure can be adjusted so that the ejector 14, creating some vacuum inside the filter, partially returning to the tank 4 the reagent previously pumped into the filter zone 13. The supply of compressed air to the tank 5 is continued until the floating ball valve 21 of this tank is seated on lower cone seat 17. The process is then repeated in reverse order. At the same time, the concentration of the reagent drops to 6-7%, which is sufficient to continue processing.

The end time of the reagent treatment is controlled by any known method, for example, by stabilizing the electrical resistance of the pumped liquid.

Approximately the processing time until complete dissolution of ferrous compounds formed in the inflatable area and the annular space of the ejector filter is 20 minutes in the filter and in the filter area.

In the case of processing ejector needle filters with a length of no more than 10 m and a step of not more than 3 m, it is possible to simultaneously process two consecutive needle filters at once, which almost halves the time of this operation for the entire water-leveling installation.

The installation allows processing of ejector needle filters with much higher quality than it takes place during machining (cleaning), since, besides the annular space 10 and the internal cavity of the central column 11, the reagent decolmizes the filter 12, filter zone 13.

With an increase in the productivity of the needle filter, the flow rate in the needle filter increases, and with it the sedimentation rate of ferrous compounds decreases by about 3 times and the time between treatments increases.

Thus, the periodic use of the proposed installation allows, with minimum effort, to reliably maintain the performance of the needle filters during their entire service life. Waste reagent without any damage to the environment can be drained into the technical sewage system.

Formula inventions

Claims (2)

1, Installation of reagent treatment of ejector needle filters, including a source of compressed air, a discharge pipe with a valve, a pressure gauge and a reagent tank, communicated with a reagent line, equipped with a valve, with a filter and by means of an air line with a source of compressed air, easier to do Neither the technology of processing the ejector needle filters, the installation is equipped with an additional reagent tank, one of the reagent tanks with a reagent line communicating with the annular space of the ejector needle filter, and the other with its internal cavity. 2. Installation according to claim 1, that is, so that each reagent-container is equipped with a cylindrical perforated insert with upper and lower conical seats and a floating ball valve placed inside the insert, and the lower conical sedpo communicated with the reagent line, and the top - with the waste pipeline. inside Order 1284/33 Random polygons pr-tie, g, Uzhgorod, st. Project, 4 Circulation 533 Subscription