EP1973851A2

EP1973851A2 - Household effluent purification plant

Info

Publication number: EP1973851A2
Application number: EP07718242A
Authority: EP
Inventors: Bernard Beaulieu
Original assignee: Individual
Current assignee: Individual
Priority date: 2006-01-20
Filing date: 2007-01-09
Publication date: 2008-10-01
Also published as: US8048298B2; FR2896433B1; WO2007083053A3; FR2896433A1; CA2636415A1; US20110192780A1; WO2007083053A2

Abstract

Plant comprising a homogenization tank (100) equipped with a stirrer (120) and with a pumping unit (140), a connecting pipe (300) leaving the pumping unit (140) comprising an injector of reagents (310) and a static mixer (320), a second chamber (200) surmounted by a mixing tank (210) into which the connecting pipe (300, 320) opens tangentially and comprising a flocculation pan (220) above the sludge pit (230) and surmounted by a filtration chamber (240), a pipe (270) leading down to the bottom (222) of the flocculation pan (220) and a bypass pipe (160).

Description

"Domestic effluent purification plant" Field of the invention

The present invention relates to a domestic effluent purification plant comprising - a homogenization tank receiving the efïluents,

a flocculation tank comprising a frustoconical upper portion extended from a lower part, placed inside the clarification tank and in which sludge flakes are formed,

a descending pipe connecting the homogenization tank to the lower part of the flocculation tank, the effluents passing from bottom to top and clarifying on contact with the sludge flakes,

the duct comprising an upper tube whose one end is connected to the homogenization tank and the other end opens into a lower tube of greater diameter than that of the upper tube, the lower end of which opens into the part bottom of the flocculation tray,

- A sludge tank that receives sludge overflowing the flocculation tray. State of the art

Such an effluent purification plant is already known for industrial applications for the treatment of relatively large volumes, if necessary heavily loaded with pollutants.

Therefore, such an installation is not suitable for the treatment of domestic effluents in small quantities or low pollutants because, in addition to dimensional issues, the operation of the installation, even reduced to an appropriate scale, would not be effective with a very low batch rate and even the installation could clog.

OBJECT OF THE INVENTION The object of the present invention is to develop a domestic effluent purification plant of simple structure, easy to use and maintain, of small size and compatible with a domestic application, that is to say with relatively low and discontinuous effluent flows. Description and advantages of the invention

For this purpose, the present invention relates to an effluent purification plant of the type defined above characterized in that A- a first chamber forming the homogenization tank equipped with an agitator and a pumping unit, B- a connecting line at the outlet of the pumping unit, comprising a reagent injector and a static mixer, C a second chamber surmounted by a mixing tank into which the connecting line opens tangentially, and comprising

- an inverted truncated cone flocculation tank placed above the sludge tank and surmounted by a filtration chamber, the flocculation tank having in the upper part, gills for the passage of sludge flakes,

a pipe descending from the mixing tank to the bottom of the flocculation tank,

- and a purified water outlet above the filtration chamber, D- a bypass line connecting the upper part of the homogenization tank, under the effluent inlet level directly to the sludge tank.

This installation of a realization and a simple implementation, allows a normal dynamic operation by control of the agitator, and the pumping unit which provide volumes of homogenized effluents to the second enclosure in which is done sludge separation and final filtering. But this normal operation also allows a backup operation, static purely biological, that is to say without injection of reagents or stirring and pumping, limiting the operation to the most liquid parts and temporarily leaving the solid particles at bottom of the homogenization tank. When the plant can again function dynamically, the solid particles deposited at the bottom of the tank are resuspended with the stirrer to obtain a homogeneous liquid taken up by the pumping unit, which is equipped with a knife pump. fractionates the components to obtain a more homogeneous mixture with smaller particles which then arrive in the second chamber. The maintenance of the installation is done without difficulty. Normal maintenance, ie the filling of reagent reservoirs, does not present any particular difficulties and, in case of equipment problems, the agitator and the pump unit are easily accessible in the first enclosure. Any clogged pipes are also very accessible: just disassemble some fittings to access the part requiring further intervention.

Finally, the evacuation of sludge is also simple in the outlet of the upstream tank. According to another characteristic, the pumping unit is a fractionation pumping unit which allows a reduction in the size of the solid parts of the effluents.

According to another characteristic, the arrival of effluents in the homogenization tank is by a dip tube. This dip tube makes it possible, in case of stopping the pumping unit, to separate a maximum of heavy elements in the homogenization tank so that the static operation makes it possible to withdraw the less-loaded liquid in the upper part of the tank. homogenization directly in the sludge tank, when the agitator stops. According to another characteristic, the descending pipe connecting the outlet of the mixing tank to the flocculation tank is projecting into the mixing tank and its upper part is equipped with a helical guide, as its outlet upstream of a chamber of flow calm in the form of two inverted cone trunks connected by their large base.

The setting in rotation movement of the liquid or more exactly in helical movement favors the mixing and then the agglutination of the particles to develop flocks during the slow rise of the liquid in the flocculation tank. Advantageously, the pipe leaving the mixing tank is equipped with a reagent injection point followed by a static mixer to join a portion of the downcomer, of much greater cross section, before opening into the tank. flocculation.

Advantageously, the flocculation tank has a casing in the form of a double truncated cone flaring upwards and the descending duct opens into the volume defined by the small truncated cone, the casing having openings for passage flakes of mud near its top edge.

The gills are preferably divided into two peripheral rows arranged in a staggered manner so that the flocks that agglutinate and ascend more and more slowly along the wall of the flocculation tray, because of the shape more and more flared of it and consequent slowdown of the liquid, thus arrive necessarily in front of a hearing to overflow it and fall back into the sludge tank.

Advantageously, the bottom of the sludge tank is inclined towards the outlet. According to another feature, the filtration chamber is constituted by a filter mass enriched with organic powders and this chamber occupies the entire section of the chamber between the top of the flocculation tray and the outlet. This filter mass is replaced. Drawings The present invention will be described hereinafter in more detail with the aid of an example of a domestic effluent purification plant shown in the single appended figure which is a schematic sectional view of the plant. DESCRIPTION OF AN EMBODIMENT OF THE INVENTION According to the figure, the invention relates to a domestic effluent purification installation, composed of a first chamber 100 of cylindrical shape, constituting a homogenization tank receiving the effluents to be treated. . This homogenization tank 100 is connected by a connecting pipe 300 to a second chamber 200 surmounted by a mixing tank 210. The second chamber 200 contains a flocculation tank 220 into which the liquid of the mixing tank 210 for flocculating sludge which passes in the form of flakes in the sludge tank 230 to be periodically evacuated. The water separated from the sludge rises through a filtration chamber 240 to the outlet.

In more detail, the first enclosure 100 is a cylindrical structure of circular section provided with an effluent inlet 110 constituted by a bent tube, plunging. This tank 100 is equipped with an agitator 120 driven by an electric motor 121 installed on the top 130 of the tank 100 and operating in a controlled manner for example periodically and / or depending on the arrival of liquid. The tank 100 is equipped with a pumping unit 140 installed at the bottom 111 of the tank 100 in a cage 112 communicating with the rest of the tank and protecting the pumping unit. The pumping unit 140 comprises a knife rotor so as to shred and homogenize the products in suspension in the pumped effluents. The discharge side 141 of the pump is connected to the connecting pipe 300, which goes up inside the tank 100 to get over the second enclosure 200 and lead tangentially into the mixing tank 210. This connecting pipe 300 comprises at the output an injector of reagents 310 and then a static mixer 320, that is to say a path in which the reagents naturally feed the liquid flow to lead tangentially into the mixing tank 210. The tangential inlet creates a vortex flow of the liquid in the mixing chamber.

Above the first enclosure 100 is the motor 121 of the agitator 120 as well as reservoirs 150, 151 containing the reactive agent (s) to be injected into the connecting pipe 300. These equipment are easily accessible for maintenance. and the filling of the tanks 150, 151. The top 130 of the tank 100 is removable and comprises a hatch 131 for extracting the pumping unit 140 and accessing the discharge pipe 300. The homogenization tank 100 also comprises a pipe bypass 160 whose input 161 is slightly below the level of arrival 110 of the liquid in the tank 100 and opening into the sludge tank 230 of the second chamber 200. In this example, the first chamber is cylindrical with circular section YY axis. The second chamber 200, also constituted by a cylindrical volume of circular section, ZZ axis, consists of bottom up, the sludge tank 230, the bottom 231 is inclined to the outlet 232 sludge pumping. Above the bottom 231, the sludge tank 230 houses the flocculation tank 220 formed by a biconical envelope flaring upwards and terminating in an edge 221 to be carried by a perforated flange 250 fixed to the wall of the enclosure 200. Above this vessel 220, there is a volume of stillness and distribution 260 surmounted by the filtration chamber 240 constituted by a thick disc loaded with a filtering mass containing biological powders so as to ensure the final filtration of the cleaned water.

In the ZZ axis of the enclosure 200, the descending conduit 270 connects the mixing tank 210 to the base of the flocculation tank 220. This downward conduit 270 consists of an upper portion 271 projecting into the vessel of mixing 210 so as to enhance the vortex movement of the liquid arriving from the static mixer into the mixing tank. In the upper part, the inlet of this duct is provided with a helical guide 272 oriented so as to maintain the vortex movement of the liquid inside the descending duct 270 equipped with a point reagent injection 310 '. This duct 270 is extended by a static mixer 273, that is to say a path in which the reagents are mixed with the flow of liquid to open into a downward pipe portion 274 of much larger section to reach the tank. flocculation 220.

The different parts of the downcomer 270 are connected by connectors such as the connector 271, facilitating the assembly and disassembly of this part of the installation, for example for maintenance work. Under the filtration chamber 240, the descending conduit 274 increases markedly in section to arrive in the flocculation tank 220 and its output ends with a shell 275 in the form of a double truncated cone constituting a plenum of the flow. Upstream of this plenum, the portion 274 of the duct is again equipped with a helical guide 276 still to support the helical movement of the flow on arrival in the plenum 275. The bottom of the plenum is open above the bottom of the lower portion 222 of the flocculation tank 220.

The flocculation tank 220 comprises, in the upper part, two rows of louvers 223, offset with respect to each other and constituting outlets for the sludge flakes FB.

The sludge is flaked in fluff in the liquid which rises in the flocculation tank 220 decreasing in speed as a function of the section increase of the tank. The sludge flakes FB driven by the slow movement of liquid along the wall 224 of the flocculation tank 220 can thus rise and escape through the openings 223 to fall by gravity to the bottom 231 of the sludge tank 230. The cleaned water of a large portion of its sludge then rises in the plenum and distribution chamber 260 above the flocculation tank 220 to then pass through the filter chamber 240 and escape in a filtered state through the outlet 241.

The installation and the assembly of the installation are done in a simple way. All the components of the homogenization tank 100 can be put in place after installation of the tank itself. It is the same for the second chamber 200 which first receives the flocculation tank 220 and the filter chamber 240 to which is fixed by a connection, the third portion 274 of the down pipe 270. After this establishment, the upper part 271 of the pipe is fixed downstream by a connector and the mixing tank 210 is installed. The connection of the mixing tank 210 with the static mixer 320 and its connection to the discharge pipe 300 of the pumping unit 140 is also done by simple connections. If there is a problem with a component of the installation, it is easy to access this component or extract it. Thus, the motor 121 of the stirrer 120 is directly accessible above the homogenization tank 100. The pumping unit 140 can be extracted from the homogenization tank 100 because it is in principle simply placed in its position. 112. The access to the discharge pipe 300 is done by simply removing a fitting. Although the second chamber 200 has only static elements, in exceptional case of jamming, all the elements is accessible from above.

The effluent purification plant described above operates in the following manner: the effluents generally arrive discontinuously in the homogenization tank 100 through the dip tube 110. These effluents are mixed by the stirrer 120 to be homogenized before being sucked by the pump 140 whose knives shred the solid elements to have elements of a size less than a fixed limit. The knife pump 140 is for example controlled by a float and / or a clock so as to periodically pump a certain volume of effluents. This volume of effluents is homogenized by the agitator 120 before being pumped.

The effluents thus pumped pass into the injector of reagents 310 where they receive reactive agents which promote their downstream treatment. The reactive agents are mixed with the effluents in the static mixer 320 and the flow arrives tangentially in the mixing tank 210 in which it rotates in a vortexing motion to pass in the down pipe 270 in which this circular movement is supported by the guide helical 271 of the entrance. The liquid descends into the pipe 276 in a rotational movement reactivated near the outlet of the pipe, upstream of the plenum 275. In this chamber, the flow continues to rotate in a helical movement to pass into the flocculation tank. 220. The gradual increase in section slows down the flow, which becomes very slow in the flocculation tray. The effluent stream gradually separates from FB sludge flakes and the cleaned liquid goes back into the plenum 260 before passing through the filter chamber 240 and pass through the outlet 241.

The level of liquid in the second chamber 200 is set by the height of the outlet 241 of filtered water while the liquid level in the first chamber 100 varies depending on the volumes pumped. The bypass line 160 which connects the upper part of the homogenization tank 100 to the sludge tank 230 allows static operation of the plant in the event of failure of the pumping unit 140. The liquid of the homogenization tank 100 is taken from its upper part, freed from the main solid parts which, at rest of the agitator 120, descend by gravity to the bottom of the homogenization tank and are not mixed. The liquid near the upper level of the tank then passes the sludge chamber 230 in which it gets rid of a smaller fraction of solid particles than if it had been added flocculation reagents as normal regime. Then, the liquid rises through the perforated flange 250 and, possibly, the gills 224 of the flocculation tank 220 to pass through the filter mass 240 and be evacuated.

Claims

R E V E N D I C AT IO N S 1 °) Domestic effluent purification plant including

a homogenization tank receiving the effluents,

a descending duct connecting the homogenization tank to the lower part of the flocculation tank which effluents pass from bottom to top and are clarified on contact with the sludge flakes, the duct comprising an upper tube whose one end is connected to the homogenizing tank and the other end opens into a lower tube of larger diameter than that of the upper tube, the lower end thereof opening into the lower part of the flocculation tank, - a receiving sludge tank the sludge overflowing from the flocculation tank, characterized by A- a first chamber (100) forming the homogenization tank equipped with an agitator (120) and a pumping unit (140),

B- a connecting line (300) at the outlet of the pumping unit (140), comprising a reagent injector (310) and a static mixer (320),

C- a second chamber (200) surmounted by a mixing tank (210) into which the connecting pipe (300, 320) opens tangentially, and comprising - an inverted truncated cone flocculation tank (220) placed above the sludge tank (230) and surmounted by a filter chamber (240), the flocculation tank (220) having, in the upper part, gills (224) for the passage of the sludge flakes (FB) a line (270) descending from the mixing tank (210) to the bottom (222) of the flocculation tank (220),

- and an outlet (241) of the waters of the filtration chamber (240), D- a bypass line (160) connecting the upper part of the homogenization tank (100), under the arrival level of the efluent, directly to the sludge tank (230).

2 °) Installation according to claim 1, characterized in that the pumping unit (140) is a fractionation pumping unit.

3 °) Installation according to claim 1, characterized in that the arrival of effluents in the homogenization tank is performed by a dip tube (110).

4) Installation according to claim 1, characterized in that the downstream duct (270) connecting the outlet of the mixing tank (210) to the flocculation tank (220) in the mixing tank (210) and its upper part is equipped with a helical guide (211), its output being also provided with a helical guide (276) upstream of a flow plenum (275) in the form of two inverted cone truncated connected by their large base.

5 °) Installation according to claim 1, characterized in that the pipe (270) leaving the mixing tank (210) is equipped with a reagent injection point (310 ') followed by a static mixer (373). ) to join a portion (274) of the descending pipe (270) of much larger section before opening into the flocculation tank (220).

6 °) Installation according to claim 1, characterized in that the flocculation tank (220) has a casing in the form of a double truncated cone flaring upwards and the descending duct (270) opens into the defined volume by the small truncated cone (222), the casing having gills (224) passing the sludge flakes (FB) near its upper edge.

7 °) Installation according to claim 1, characterized in that the filtration chamber (240) is constituted by a filter mass enriched with biological powders. 8 °) Installation according to claim 1, characterized in that the bottom (231) of the sludge tank (230) is inclined towards the outlet.