RU227598U1 - Device for biological treatment of water and wastewater - Google Patents

Abstract

The utility model relates to bioenergy devices, in particular to devices for the purification of mine water, industrial and waste water, sewage treatment plants, and waste water drains. The device contains a reservoir equipped with means for supplying purified water, supplying a fluid medium carrying a reaction gas for the purification process, removing purified water and excess gas, a carrier material configured to develop a biofilm on it, and a logical control device. The cross section of the tank is made round. The fluid supply means are located on the wall of the tank. The reservoir is equipped with fluid supply controls that ensure rotation of the carrier material, water and the medium carrying the reaction gas around an axis passing through the center of the cross section of the reservoir. The inner surface of the tank is made smooth. A protective casing containing an aeration channel is provided around the tank. The protective casing is made with a vertical settling well. Along the side wall of the tank there is an aeration channel with a protective screen installed with a gap between it and the tank wall. The gap size is less than the diameter of the medium supply means, made in the form of a flexible aerobic hose made of porous breathable material and placed in the aeration channel. One end of the hose is connected to a compressor located in the settling well, and the other is stretched along the aeration channel to the outer end wall of the tank. The aerobic sleeve is installed with the possibility of dismantling. The settling well contains a logical control device, a water and sludge softening partition installed along the inner end wall of the tank, made with perforated holes, and purified water drainage. Technical result: the ability to dismantle and replace the reaction gas supply means, which facilitates maintenance of the bioreactor without digging it out of the ground. 3 ill.

Description

The utility model relates to bioenergy devices, in particular to devices for the purification of mine water, industrial and waste water, sewage treatment plants, and waste water drains.

There are known methods of cleaning using biofilm, in which the carrier material is in motion during the cleaning process (patents US 6126829, MPK B01J19/30, C02F 3/08; C02F 3/10, 2000; US 5458779, MPK E04D 15/07, 1979 ; US 5543039, MPK C02F 3/00, C02F 3/08, C02F 3/10, C02F 3/12 C02F 3/28, C02F, 1994). The advantage of known moving bed reactors is a significant reduction in the degree of clogging of the carrier material and the development of inactive zones. The surface of the carrier material elements is partially protected from collisions with other carrier material elements.

The disadvantage of known reactors is the significantly limited capacity of the purification process due to the fact that an extremely low degree of filling is required, for example, about 30-70% of the reactor volume is empty in order to provide the elements of the carrier material with the possibility of free movement in the water being purified. Accordingly, the capacity of the pollutant removal process is less than in the case of a fixed bed reactor, given the same reactor volume and the same carrier material, since the fixed bed reactor allows for a larger loading capacity.

The closest in technical essence to the claimed device is a bioreactor for water purification selected as a prototype (RF patent 2377190, IPC C01F 3/08, C01F 3/20, B01J 19/30, 2006) including a reservoir, means for supplying purified water and reaction gas , means for removing purified water and excess gas and elements of the carrier material, providing for the possibility of biofilm developing on them.

The disadvantage of the known device is the difficulty of servicing the air supply channel, inside of which there are many outlet elements and membranes that interfere with that operation.

The technical result consists in the possibility of dismantling and replacing the means of supplying the reaction gas, which facilitates maintenance of the bioreactor without digging it out of the ground.

The technical result is achieved by the fact that in a device for biological water purification containing a reservoir equipped with means for supplying purified water, supplying a fluid medium carrying a reaction gas for the purification process, removing purified water and excess gas, a carrier material capable of developing on it biofilms, logical control device, the cross-section of the tank is made round, in which the fluid supply means are located on the wall of the tank, the tank is equipped with fluid supply controls that ensure rotation of the carrier material, water and the medium carrying the reaction gas, around an axis passing through the center of the cross section of the tank, the degree of filling of the tank with carrier material is up to 100%, the inner surface of the tank is made smooth, a protective casing is provided around the tank, containing an aeration channel, according to the utility model , the protective casing is made with a vertical settling well, an aeration channel is placed along the side wall of the tank a channel with a protective screen installed with a gap between it and the wall of the tank, wherein the gap size is less than the diameter of the medium supply means, made in the form of a flexible aerobic hose made of porous air-permeable material and placed in the aeration channel, one end of the hose is connected to a compressor located in the settling well, and the other is stretched along the aeration channel to the outer end wall of the tank, the aerobic sleeve is installed with the possibility of dismantling, and the settling well contains a logical control device, a water and sludge softening partition installed along the inner end wall of the tank, made with perforated holes, and drainage of purified water.

The utility model is illustrated by drawings.

In fig. 1 shows a device for biological water and wastewater treatment, side view; in fig. 2 – the same, section A-A; in fig. 3 the same, longitudinal section.

A device for biological purification of water and wastewater (bioreactor) contains a cylindrical tank 1 of circular cross-section, equipped with means for supplying 2 purified water and discharging 3 purified water, means for supplying a medium carrying the reaction gas necessary for the purification process, and for removing excess air and gas through ventilation duct 4.

The tank 1 has a smooth inner surface and is placed in a protective casing 5, made with a vertical settling well 6 located at the end of the tank 1. The means of supplying 2 purified water and the channel 4 for excess air can be located in its upper part or anywhere in the tank 1 , so that the supply 2 of purified water and the removal 3 of purified water and excess gas are carried out with the condition that the tank 1 is almost completely filled during the cleaning process.

In the water being purified, bubbles 7 of the reaction gas are formed, for example, in the case of air supply, air bubbles 7 are formed, necessary for the aerobic cleaning method. Air bubbles 7 dissolve in water, saturating it with oxygen necessary for the development of bacteria. The fluid may also contain pre-aired water, where the air is present in the form of aeration bubbles 7 and/or in a pre-dissolved form, thereby producing oxygenated water.

It is possible to supply 2 purified water in a periodic mode, when the tank 1 is completely filled with purified water.

Inside the reservoir 1 there is a carrier material 8 (bioload), which allows for the development of microorganisms on it with the formation of a biofilm. The carrier material 8 may consist, for example, of one element, a plurality of firmly connected elements of the carrier material 8, and a plurality of individual elements of the carrier material 8, and, in the latter case, the elements of the carrier material 8 may be the same or different in size, shape , density and/or other properties.

The carrier material 8, rotating in a circle inside the bioreactor, passes through the zone of air bubbles and captures them. As a result, part of the air rotates for some time together with the carrier material 8. This creates conditions for better saturation of water with oxygen. The degree of filling of the reservoir 1 with carrier material 8 is up to 100%.

The means for supplying the medium (air, reaction gas) is placed in the supply aeration channel 9 and is made in the form of a flexible aerobic hose 10 made of a porous breathable material, for example, porous rubber or polyurethane. There can be several such aeration elements and they are installed on the inner wall of the tank 1.

The sleeve 10 is connected at one end to a flexible or rigid tube 11, which passes through a hole in the wall of the tank 1, in which, for example, an oil seal or sealing coupling 12 is installed, preventing the escape of air and water. Next, it is connected to a compressor 13 installed in the settling well 6 or outside. The other end of the hose 10 is stretched through the entire aeration channel 9 along the protective screen 14 to the opposite end of the tank 1. The hose 10 is installed with the possibility of dismantling: if the installation is located above ground, then dismantling occurs from the outside of the bioreactor, and if it is buried in the ground - with access from settling well 6. The compressor 13 is located in the upper part of the settling well 6 above the liquid level. This may be a removable bottom or a specially made platform.

The aeration sleeve 10 passes gas (air) only in one direction through the pores of the shell of the sleeve 10. The aeration channel 9 is separated from the main part of the tank 1 by a protective screen 14 installed with a gap 15 between it and the wall, while the gap 15 is less than the diameter of the aeration sleeve 10. Making the sleeve 10 from a porous, breathable material allows the flow of supplied air to evenly penetrate into the tank 1 with purified water in the form of small air bubbles 7, excluding the reverse penetration of water into it.

The porous material of the sleeve 10 promotes the formation of fine bubbles 7 over its entire area and improves the quality and speed of biological treatment in the bioreactor. The number of bubbles 7, which are attached to the carrier material (bioload) 8, increases, thereby increasing the mass transfer characteristics of the incoming air.

It has been established that the smaller the size of the air bubbles 7, the less their ability to stay on the surface of the water, and therefore the smaller air bubbles 7 rotate in the bioreactor more freely, in the same direction with the elements of the carrier material 7, which, in turn, move around the horizontal axis of rotation passing through the center of the cross section of tank 1.

In the end wall of the tank 1 from the side of the settling well 6, there are perforations 16. The settling well 6 contains a cover 17, a water softening partition 18 located along the end wall of the tank 1, an outlet for return water and sludge 19, a return or removal means settled sludge 20, clean water drainage 3, compressor 13 and a logical device for controlling the operation of the bioreactor, with which it is possible, if necessary, to close the supply valves of various channels. (not shown in figure).

The logic device may be an electronic or mechanical timer, a programmable relay, or a programmable logic controller. These elements can control both pump activation and air supply from the compressor.

The damper partition 18 can be made of any type of plastic or polyethylene that is resistant to aggressive environments and does not absorb moisture. Structurally, the damper partition is placed next to the wall of the working compartment with perforation, at a distance of 5-10 centimeters from it and does not reach the bottom 10-20 cm to ensure the removal of silt particles entering with water.

All equipment is installed with the possibility of dismantling. Dismantling of the equipment is necessary to provide operator access to the attachment point for the aerobic hose 9 on the end wall of the tank 1 from the side of the settling well 6 in the case of underground installation of the bioreactor.

The device works as follows.

Initially, wastewater enters a septic tank or receiving chamber (not shown in the figure), in which non-decomposable sediment (hair, residues, food, hygiene items) is deposited, then it flows by gravity into the supply tank (not shown in the figure) , in which a drainage pump or other means of pumping liquid is installed, for example an airlift. The supply tank can be made separately, or in the form of a single block with a septic tank, or a single block with a bioreactor. From the supply tank with a drainage pump, but a gravity-flow version is also possible, as it enters or in portions, wastewater is supplied to the bioreactor tank 1, which is filled with bioloading elements 8.

Air (gas) in the form of air bubbles 7 enters the working area 21 of the tank 1 through the gap 15 under pressure to saturate the water with oxygen and rotate the carrier material 8, which rotates in one direction around the axis of rotation passing through the center of the tank 1. Periodically into the tank 1, a new portion of purified water is supplied, the purified liquid is removed by displacement and the process is repeated.

Air is supplied to the aeration sleeve 9 using a compressor 13. There can be several such aeration elements and they are installed on the inner wall of the tank 1. Next, gas bubbles 7 through the gap 15 enter the working area 21, where, partially attached to the bioload 8, they provide rotational movement relative to the center line of the tank 1. Excess air and gas formed during the biological treatment process are removed through the ventilation channel 4, which can be made as a single unit with the body, for example by rotomolding, or in the form of a separate element welded to the body 1 from the outer part . During the cleaning process, sludge is formed, which moves along with the biological load 8. Subsequent drains displace the sludge through perforated holes 16 in the end wall of the tank 1 into the settling well 6, in which a water softening partition 18 is installed, which prevents mixing of the liquid and creates conditions for sedimentation silt sediment.

Then, by means of sludge return (pump or airlift), the sludge is returned to the septic tank. Coagulants can be used to maximize phosphorus removal and improve sediment formation. The settled and purified water is removed through a special channel. The settling well 6 is designed in such a way that it can accommodate an installer who, having disconnected the supply air line, can dismantle the oil seal or coupling 12 and remove the aeration hose 10 from the aeration channel 9. Installation of the new aeration hose 10 is performed in the reverse order. In the case of a ground-based installation of the bioreactor, the seals 12 can be placed on the outer wall of the tank 1, then replacing the hose 10 will not require installation work.

Most of these treatment facilities are installed by installing them in the ground, which makes maintenance difficult or impossible.

The use of the utility model makes it possible to dismantle and replace the means of supplying the reaction gas, which will facilitate the maintenance of the bioreactor without digging it out of the ground.

Claims (1)

A device for biological water purification, containing a reservoir equipped with means for supplying purified water, supplying a fluid medium carrying a reaction gas for the purification process, removing purified water and excess gas, a carrier material configured to develop a biofilm on it, a logical control device, transverse the cross section of the tank is made round, in which the fluid supply means are located on the wall of the tank, the tank is equipped with fluid supply control means that ensure rotation of the carrier material, water and the medium carrying the reaction gas around an axis passing through the center of the cross section of the tank, the degree of filling carrier material of the tank up to 100%, the inner surface of the tank is made smooth, there is a protective casing around the tank containing an aeration channel, characterized in that the protective casing is made with a vertical settling well, along the side wall of the tank there is an aeration channel with a protective screen installed with gap between it and the wall of the tank, while the gap value is less than the diameter of the medium supply means, made in the form of a flexible aerobic hose made of porous air-permeable material and placed in the aeration channel, one end of the hose is connected to a compressor located in a settling well, and the other stretched along the aeration channel to the outer end wall of the tank, the aerobic sleeve is installed with the possibility of dismantling, and the settling well contains a logical control device, a partition-water and sludge softener installed along the inner end wall of the tank, made with perforated holes, drainage of purified water.