RU115776U1 - INSTALLATION OF CLEANING OF STRAIN STRAINS FROM OIL PRODUCTS AND WEIGHTED PARTICLES - Google Patents

Abstract

1. Installation for cleaning storm water from oil products and suspended particles, containing a receiving chamber, a settling tank and a filtration chamber with a sorption filler, separated by partitions with overflow holes, inspection wells with hatches, an inlet manifold and an outlet pipe, characterized in that it additionally contains a stilling chamber, located between the settler and the filtration chamber, the inlet collector of the receiving chamber is made with a conical nozzle to reduce the speed of storm drains, and in the receiving chamber itself there is a removable mesh basket with a blank base in the form of a trapezoidal hopper, and the front wall of the basket is in contact with the conical nozzle and is made inclined coalescent plates are installed in the sump, and the filtration chamber consists of two sections separated by a perforated partition; removable baskets with vertical flat with cassettes filled with adsorbent, in addition, inspection wells with hatches for the receiving chamber and the settling tank are equipped with submersible centrifugal pumps to remove surfaced oil products, and a perforated pipe is installed at the bottom of the installation along its axis for washing the chambers. ! 2. Installation according to claim 1, characterized in that the conical nozzle of the inlet manifold is made with a taper of 120-125 °. ! 3. Installation according to claim 1, characterized in that an organic sorbent, which is a waste of agricultural production, is used as a filler in the filtration chambers. ! 4. Installation according to claim 1, characterized in that

Description

The installation relates to treatment facilities for cleaning storm water from oil products and suspended particles and can be used in the treatment of rainwater from the territories of car parks and gas stations.

A known unit for cleaning oily wastewater containing a receiving chamber-settler, a thin layer filter, at least one filter with sorbent filler, made in the form of a cube with metal side walls and mesh upper and lower walls. (Patent No. 99479 C02F 1/40 published May 18, 2010). The disadvantage of such a device is its ground location, which requires the supply of wastewater that has been pre-treated in sand traps using pumping equipment.

The closest analogue to the claimed utility model is the installation for the treatment of storm, melt and industrial wastewater Veksa, Veksa-M TU 485912-001-98116734-2007 (developed by Ecostroy LLC, 150014, Yaroslavl, Lisitsina St., 56) . The unit is intended for the treatment of storm, melt, industrial and irrigation wastewater contaminated with oil products and suspended solids discharged from the territories of industrial enterprises and residential (populated) territories.

The installation is housed in a fiberglass housing and contains a sand trap separated by partitions, a thin-layer sump, a filtration zone containing sorption filters of the first and second stages of treatment. The input and output of storm drains is carried out through pipes with a cylindrical bell-shaped connection. The installation also includes a storage tank and a bypass line.

The disadvantage of this installation is the reduced degree of purification from pollution during volley storm discharges. To eliminate it, a storage tank and a bypass line to it are required in order to reduce the volumetric flow rate through the installation, which further increases its cost.

The objective of the utility model is to create an installation for the treatment of storm drains from oil products and suspended particles that works efficiently during volley storm discharges.

The technical result is to increase the cleaning efficiency during the period of volley storm discharges without the need for a storage tank and a bypass line to it, which simplifies the apparatus design and reduces the cost of its manufacture and operation.

The technical result is achieved by the fact that the installation for cleaning storm water from oil products and suspended particles contains a receiving chamber, a sump and a filter chamber with sorption filler, separated by partitions with overflow openings, inspection wells with hatches, an inlet manifold and an outlet pipe. The installation further comprises a stilling chamber located between the sump and the filter chamber. The inlet manifold of the receiving chamber is made with a conical nozzle to reduce the velocity of storm drains, and a removable mesh basket with a blank base in the form of a trapezoidal section bin is installed in the receiving chamber itself. Moreover, the front wall of the basket is in contact with the conical nozzle and is made of a lattice with a larger gap than the lattices of the remaining walls. In the sump, inclined coalescent plates are installed, and the filtration chamber consists of two sections separated by a perforated partition. In sections, removable baskets with vertical flat cartridges filled with adsorbent are installed. Inspection wells with hatches of the receiving chamber and the sump are equipped with submersible centrifugal pumps to remove floating oil products, and at the bottom of the installation, along its axis, a perforated pipe is installed for washing the chambers.

The nozzles of the inlet collector are made with a taper of 120-125 °, which allows to drastically reduce the speed of the volley storm drains, which creates favorable conditions for the deposition of suspended particles in the trapezoidal section of the mesh basket.

An additional stilling chamber is equipped between the sump and the filtration chamber, designed to evenly distribute the flow supplied for cleaning to the filtration chamber filled with vertical flat cartridges with an effective sorbent that ensures a degree of cleaning that meets sanitary standards. An organic sorbent, which is a waste of agricultural production, is used as a filler in the filtration chambers, which reduces the cost of manufacturing the installation.

The casing of the installation is made of a polyethylene pipe of the Korsis type, which allows reducing labor costs in the manufacture of the installation. For the convenience and efficiency of periodic cleaning of the installation from precipitated contaminants, a perforated polyethylene pipe passing along the bottom of the installation was used, into which the washing water is supplied by a centrifugal pump.

The essence of the claimed utility model is illustrated by figure 1, which shows a schematic diagram of the installation.

Installation for cleaning storm drains from oil products and suspended particles includes a receiving chamber 1 with an inlet collector 2 having a conical nozzle 3, a mesh basket 4 for separating floating and large suspended particles, a settling chamber 5 with coalescent plates 6 made of reinforced polycarbonate, a stilling chamber 7, a two-section filter chamber 8 filled with vertical flat cartridges 26 with adsorbent. For ease of maintenance, three cylindrical hatches are provided in the upper part of the cylindrical body, 9, 10, 11 of a diameter smaller than the body and located above the periodically serviced installation chambers. The mesh basket 4 for ease of dismantling moves along the runners 12. The periodically used centrifugal small-sized submersible pump 13 can be placed at the level of the oil layer both in the receiving chamber 1 and in the settling chamber 5. To organize the flow structure, which facilitates the efficient deposition of suspended particles and coalescence drops of oil products, the drain passes through round holes 14 and 18 in the partitions 15 and 19, as well as through the segment cutouts 17, 21 in the reflective partitions 16, 20. Perforated partitions 22, 24, 27 allow passage of the cleaned drain into the mesh baskets 23, 25 filled with flat vertical cassettes 26 containing the sorbent. The cleaned drain leaves the installation through the nozzle 28. The periodically used centrifugal pump 29 serves to supply wash water to the perforated polyethylene pipe 30.

The installation is as follows.

Storm drains enter the receiving chamber 1 through the inlet manifold 2, which has conical nozzles 3 at the end, and enter the mesh basket 4, the front wall of which is made of a grating with a large amount of openings, which allows large particles to pass through. Due to the conical nozzle 3, which comes close to the front wall of the mesh basket 4, during volley storm discharges, a sharp decrease in the flow rate occurs and favorable conditions are created for the precipitation of suspended particles in the trapezoidal section of the mesh basket 4 and the conditions for coalescence of small drops of oil products and removal of some from them together with the precipitate due to adhesion. In addition, conical nozzles 3 are used to reduce hydraulic resistance at the outlet of the collector 2. A mesh basket 4 with a trapezoidal section hopper is used to collect particles that have fallen and precipitated, which can be periodically removed when the basket 4 is lifted through the hatch 9 along sliding guide rails 12 to the protected area for complete cleaning of trapped pollution. In the receiving chamber 1 is the separation of the bulk of the oil floating on the surface. The accumulation of oil products in the disposal tank is carried out using a periodically used submersible centrifugal pump 13. Further, the storm drain passes through the side and rear walls of the mesh basket 4, made of fine mesh, which trap small floating particles. After this, the storm drain is directed to the round hole 14 in the overflow wall 15. The round hole 14 is located below the liquid level in the receiving chamber 1 to prevent oil products accumulated on the water surface from the receiving chamber 1 into the settling chamber 5. Then, the storm drain falls down between the overflow wall 15 and the reflector wall 16 and passes under the segment cutout 17 in the reflector wall 16. After passing through the segment cutout 17, the storm drain is directed upward into the settling chamber 5 and distributed between the inclined oalescent plates 6 made of reinforced polycarbonate, where intense coalescence of oil product droplets and active deposition of finely divided suspended particles that did not have time to separate in the receiving chamber 1. The oil products that floated to the surface of the water from the settling chamber 5 are periodically removed to the disposal tank with a submersible centrifugal pump 13. After of the settling chamber 5, the cleaned drain is directed into the round hole 18 of the overflow partition 19, passes between the overflow partition 19 and the reflecting partition oil 20, passes through a segment cutout 21 in the baffle-reflector 20 and enters the stilling chamber 7, designed to improve the operation of the two-section filter chamber 8 during the period of volley storm discharges. From the stilling chamber 7, stormwater flows through the perforated partitions 22 and 24 into mesh baskets 23 and 25, which contain flat vertical cassettes 26 of woven material. Cassettes 26 are filled with an organic sorbent designed for adsorption of oil residues and fine suspensions that were not separated in previous chambers. The cleaned storm drain passes through the perforated partition 27 and leaves the installation through the pipe 28.

The installation is mounted on the protected area in underground execution and, thus, does not clutter it. The underground location of the installation also allows the use of gravity storm water flow and refuse to supply storm water using pumping equipment, thereby significantly reducing operating costs.

Precipitated precipitate is periodically removed from all chambers by rinsing with water supplied by a centrifugal pump 29 to a perforated polyethylene pipe 30 passing along the bottom of the cylindrical body along its axis. For the period of washing the installation from the sediment mesh baskets 4, 23, 25 are removed from the housing of the installation. Wash water is sent to a disposal tank.

Claims (4)

1. Installation for cleaning storm drains from oil products and suspended particles, containing a receiving chamber, a sump and a filter chamber with sorption filler, separated by partitions with overflow holes, manholes with hatches, an inlet manifold and an outlet pipe, characterized in that it further comprises a stilling chamber, located between the sump and the filter chamber, the inlet manifold of the receiving chamber is made with a conical nozzle to reduce the speed of movement of storm drains, and in a removable mesh basket with a blank base in the form of a trapezoidal section hopper is installed in the removable chamber, the front wall of the basket in contact with the conical nozzle and made of a grating with a larger gap than the other walls, inclined coalescent plates are installed in the sump, and the filtration chamber consists of two sections , separated by a perforated partition, removable baskets with vertical flat cartridges filled with adsorbent are installed in the sections, in addition, manholes with hatches and the receiving chamber and the sump are equipped with submersible centrifugal pumps to remove floating oil products, and at the bottom of the installation, along its axis, a perforated pipe is installed for washing the chambers. 2. Installation according to claim 1, characterized in that the conical nozzles of the inlet manifold are made with a taper of 120-125 °. 3. Installation according to claim 1, characterized in that an organic sorbent is used as a filler in the filtration chambers, which is a waste of agricultural production. 4. Installation according to claim 1, characterized in that the housing of the installation is made of polyethylene corrugated pipe of the type “Corsis”.