RU75651U1 - BIOLOGICAL WASTE WATER TREATMENT PLANT - Google Patents

Abstract

The utility model relates to the field of biological wastewater treatment.

A known installation for biological wastewater treatment, consisting of a pre-treatment unit, a bioreactor equipped with aeration systems, circulation of activated sludge from the lower part of the bioreactor to its upper part with a pump and nozzle distribution unit of activated sludge, a treatment chamber, a suspension in a centrifugal field, providing for breaking flakes during rotation, a membrane separator, a circulation system between a membrane separator and a bioreactor, pipelines for the supply of purified water and the removal of purified water and the after-treatment unit.

A disadvantage of the known installation is the design complexity, not high enough separator performance due to the formation of a colloidal precipitate on the membrane surface and the high cost of the process.

Installation for biological wastewater treatment, including a pre-treatment unit, a bioreactor with an aeration system, a membrane separator with a submersible membrane module, a purified water outlet, a purified water supply pipe and a recirculation pipe between the membrane separator and a bioreactor and a post-treatment unit, the unit is equipped with a jet tube reactor, equipped with guide longitudinal tubes hydraulically connected to the bioreactor, a perforated diaphragm is placed in the lower part of the membrane separator, in the separator bottom is equipped with a central suspension feed pipe from a jet tube reactor, and the ratio of the step of the membrane module cassettes formed by hollow fiber membranes fixed in the upper part of the cassettes to the module height is 1: 8 ÷ 1: 40. 1 s.p. f-ly, 1ill.

Description

The utility model relates to the field of biological wastewater treatment, and more particularly, to installations for biological wastewater treatment equipped with a membrane module.

A known installation for biological wastewater treatment, consisting of a ULTRAFOR 1 bioreactor equipped with a purified water supply pipe, an aeration system, a submersible membrane filter and a purified water outlet from it (see DEGREMONT, Technical Handbook for Water Treatment, second edition. Vodokanal, St. Petersburg, 2007, vol. 2, p. 917).

A disadvantage of the known installation is the decrease in its productivity due to the formation of a colloidal structure on the surface of the membranes of the membranes, which entails the need to create a site for reactant water treatment and the formation of secondary waste.

A known installation for the biological treatment of wastewater from nitrogen, phosphorus and other organic compounds, consisting of three chambers - anaerobic with a stirrer, aerobic with a polymer nozzle and a filtration chamber equipped with a hollow fiber membrane module; the aerobic chamber is divided, in turn, by screens into three sections, communicating through the upper edges of the screens or below their lower edges, aerobic conditions are created in the middle of the sections, and anoxic conditions in the other two. A pipeline of a certain configuration - with an angle of inclination of 20-90 ° with respect to its horizontal section, connecting the anaerobic and aerobic chambers, ensures the flow of wastewater from the first chamber to the second. An aerobic chamber and a filtration chamber are connected between

a buried pipeline, and the filtration chamber is connected by an overflow chute that recirculates activated sludge into the anaerobic chamber (see patent EP No. 1484287, IPC: C02F 3/30, C02F 3/12 with the priority of Portugal 02/01/2002, publ. 12/08/2004 g.).

A disadvantage of the known installation is the complexity of its design, due to the presence of additional sections in the aerobic chamber, equipped with nodes of complex configuration.

A known installation for biological wastewater treatment, the closest in purpose and technical essence to the claimed, consisting of a pre-treatment unit, a bioreactor equipped with aeration systems, circulation of activated sludge from the lower part of the bioreactor to its upper part with a pump and nozzle distribution unit of activated sludge, chamber processing, suspension in a centrifugal field, providing breakdown of flakes during rotation, a membrane separator, a circulation system between a membrane separator and a bioreactor, pipelines cottages and discharge the treated water purified water and after-treatment unit. The aeration system is made in the form of tubular membranes and paddle mixers (see patent DE No. 10105221, IPC C02F 3/12 with priority 02.02.2001, publ. 08.08.2002).

The disadvantages of the known installation are:

- the complexity of the design, due to: the presence of a circulating system of activated sludge and its distribution in the bioreactor, a membrane aeration system with paddle mixers that create, due to intensive turbulization, adverse conditions for the formation of well-structured flakes in a suspension of activated sludge;

- insufficiently high productivity, due to the use of paddle mixers,

and the presence of a centrifuge for breaking the flakes of the suspension by rotation in a centrifugal field, which is a prerequisite for the deterioration of the filterability of the suspension in the process of membrane separation, which does not eliminate the formation of a colloidal precipitate on the surface of the membranes;

- an increase in the cost of the process, which is facilitated by all of the above, as well as the use of a local pump in the circulation system of the bioreactor and the centrifuge motor.

The technical result of the proposed technical solution is to simplify, increase the productivity of the installation and its cost.

The technical result is achieved by the fact that the installation for biological wastewater treatment, including a pre-treatment unit, a bioreactor with an aeration system, a membrane separator with an immersion membrane module and a purified water outlet pipe, a purified water supply pipe, a recirculation pipe between the membrane separator and bioreactor and a water purification unit equipped with a jet tubular reactor equipped with guide longitudinal tubes hydraulically in communication with the bioreactor in the lower part of the membrane separator p zmeschena apertured diaphragm is mounted in the bottom of the separator central conduit supplying the slurry from the jet of the tubular reactor, and the step ratio cassettes membrane module, the hollow fiber membranes formed, fixed at the top of the cassettes, to the height of the module is 1: 8 ÷ 1: 40.

The drawing shows a plant for biological wastewater treatment.

Installation for biological wastewater treatment consists of a pre-treatment unit 1 with a pipeline for supplying source water 2, a bioreactor 3 with an aeration system 4, hydraulically connected with a jet tube reactor 5, equipped with distribution devices 6 at the inlet and outlet and equipped with guide longitudinal tubes 7, submersible membrane separator 8, equipped with membrane modules 9 with cassettes 10; a perforated diaphragm 11 is placed above the bottom of the membrane separator 8. A central pipe 12 is mounted in the bottom of the membrane separator 8 to feed the slurry from the jet reactor 5 into the membrane separator 8. The bundles of hollow fiber membranes are fixed at the top of the cartridges 10, with the ratio of the pitch of the cartridges 10 to the module height 9 is 1: 8 ÷ 1: 40.

The installation includes a recirculation pipe of activated sludge 13, located between the membrane separator 8 and the bioreactor 3, a post-treatment unit 14 with a pipe for draining purified water 15. The unit also includes a pipe for removing activated sludge for dewatering 16.

Installation for biological wastewater treatment works as follows:

The source water through its supply pipe 2 enters the pre-treatment unit 1, made, for example, in the form of rakes and filters, and then into the bioreactor 3, where activated sludge separated in the process of separation on hollow fiber membranes is supplied from the membrane separator 8 by recirculation pipe 13. In a bioreactor 3 equipped with an aeration system 4, for example, in the form of membrane aerators, a flocculation process takes place - the formation of flakes of organic macromolecules, supercellular polymers and filamentous microorganisms, and biosorption in the “soft mixing” mode. The resulting suspension by

the distribution device 6 enters the jet tubular reactor 5, equipped with guide longitudinal tubes 7, where, under favorable conditions of distribution and smooth flow of the stream of slurry of activated sludge, the biosorption process continues with the formation of homogeneous, well-structured flakes. As a result of the foregoing, a suspension is easily separated by membrane separation. The latter enters through the switchgear 6 of the jet pipe reactor 5 and the central pipe 12 from below into the membrane separator 8 and is distributed passing through the perforated diaphragm 11. The distributed flow of the suspension, rising upward, as it opens up bundles of hollow fiber membranes fixed in the upper part of the cartridges 10, united into modules 9, washing their surface from all sides, which helps to reduce the formation of a colloidal precipitate on the surface of the membranes. In the membrane separator 8, upon contact with the surface of the hollow fiber membranes, a membrane separation process takes place with the purified water being drained from the upper part of the separator 8. A part of the activated sludge separated during the membrane separation is fed into the bioreactor 3 through a recirculation pipe 13, and a part of the activated sludge is removed from the dewatering unit through the outlet pipe for activated sludge 16. The purified water from the membrane separator 8 enters the post-treatment unit 14, which is a filter with adsorbent, for example, activated coal, and an apparatus for disinfection and removal through the pipe 15 purified water is output outside the installation.

The claimed ratio of the pitch of the cassettes 10 formed by bundles of hollow fiber membranes fixed in the upper part of the cassettes 10 to the height of the membrane module 9-1: 8 ÷ 1: 40 provides maximum access to the diffusion flows of the shared suspension

to the surface of the disclosed beams of hollow fiber membranes, which entails an increase in the performance of the membrane separator and the installation as a whole.

When the ratio of the step of the cassettes to the height of the module is less than 1: 8, the “opening” of the membrane beams of the module is reduced, which reduces the access of diffusion fluxes to them due to a decrease in the contact area and, as a result, a decrease in productivity.

When the ratio of the cartridge pitch to the module height is more than 1:40, the installation cost increases due to the need to use a more powerful pump for feeding the suspension, i.e. increase the energy consumption of the installation.

To clean the membranes of the cartridges 10 of the module 9, periodically, reverse flow of clean water under pressure is carried out into the hollow fibers using a known technology.

The proposed installation for biological wastewater treatment in comparison with the known provides:

- simplification of the design by eliminating the circulation system of activated sludge and its distribution in the bioreactor, paddle mixers of the membrane aeration system, which, due to intensive turbulization, creates unfavorable conditions for the formation of well-structured flakes in the suspension of activated sludge and a local pump;

- increase in plant productivity due to the exclusion of paddle mixers and the replacement of the suspension treatment chamber in a centrifugal field with a tubular jet reactor equipped with tubes, where the process continues under conditions of uniform distribution over the tubes and smooth flow

biosorption with the formation of homogeneous well-structured flakes, easily separated in the separation process; the latter significantly reduces the formation of sediment on the surface of the membranes;

- cheapening the cleaning process.

Thus, the proposed installation in comparison with the known increases productivity by about 20-25%; installation cost is reduced by about 25-30%.

Claims (1)

Installation for biological wastewater treatment, including a pre-treatment unit, a bioreactor with an aeration system, a membrane separator with an immersion membrane module, a purified water outlet, a purified water supply pipe, a recirculation pipe between the membrane separator and a bioreactor and a post-treatment unit, characterized in that the installation is equipped with a jet tubular reactor equipped with guide longitudinal tubes hydraulically connected to the bioreactor, a perforator is placed in the lower part of the membrane separator a diaphragm, a central pipeline for supplying slurry from a jet tube reactor is mounted in the bottom of the separator, and the ratio of the step of the membrane module cassettes formed by hollow fiber membranes fixed in the upper part of the cassettes to the module height is 1: 8 ÷ 1: 40.