KR101835278B1 - Anaerobic granular sludge reactor - Google Patents

Abstract

The present invention relates to an anaerobic granular sludge reactor, which comprises: a plurality of distributors installed on a bottom surface of the reactor to discharge flowing waste water in a first wall surface direction of the reactor; a first baffler coupled to a first wall surface higher than the distributors within the reactor, preventing the flowing waste water from the distributors and anaerobic microorganism sludge within the reactor from being discharged in a vertical direction of the reactor, and inducing the flow in a second wall surface direction; and a second baffler coupled to a second wall surface higher than the first baffler within the reactor, preventing the flowing waste water induced by the first baffler and the anaerobic microorganism sludge from being discharged in a vertical direction of the reactor, and inducing the flow in a wall surface direction different from the second wall surface.

Description

[0001] ANAEROBIC GRANULAR SLUDGE REACTOR [0002]

The present invention relates to an anaerobic granular sludge reaction tank, and more particularly, to an anaerobic granular sludge reaction tank capable of maximizing removal of organic pollutants by anaerobic microbial sludge and minimizing loss of anaerobic microbial sludge by increasing the residence time of wastewater flowing into the reaction tank .

Numerous wastewaters are generated by industrial activities and human activities. If it enters the river or sea directly, the generated wastewater can destroy the ecosystem by polluting the river or the sea and causing serious environmental pollution. In order to prevent environmental pollution, wastewater is forced to be discharged after removing various pollutants through wastewater treatment process.

The wastewater treatment process can be carried out by various treatment processes. For example, the wastewater treatment process has a pretreatment process to treat solid waste products. In the pretreatment process, large and coarse solid waste products can be mechanically removed or small suspended solid waste products can be removed through chemical coagulation or flocculation. Pre-treatment improves 25-35% of waste water BOD.

The wastewater treatment process can reduce the BOD value by 90 ~ 98% through microbial treatment. The microbial treatment process is known as a method using aerobic microorganisms and a method using anaerobic microorganisms. Both processes can be used both in the process of decomposition of pollutants and in the process of wastewater treatment due to the decomposition of byproducts.

It is generally known that pre-treating wastewater through anaerobic granular sludge reactors is more advantageous in terms of economy and environmental purification than when using only aerobic sludge reactors (for example, aeration tanks) .

As an example of the anaerobic granular sludge reaction tank, a UASB (Upflow Anaerobic Sludge Blanket) type reaction tank is widely used. The UASB type reactor raises the incoming wastewater at the bottom of the reactor according to the hydraulic pressure and the flow rate and decomposes the pollutants and discharges the biogas through the biological reaction of the anaerobic microbial sludge having particles larger than a predetermined size with the wastewater. Biogas can be, for example, CO2 and CH4.

In this way, the UASB-type reaction tank rises vertically in the upward direction with the weir, and the accumulated anaerobic microbial sludge layer reacts with the rising wastewater to remove contaminants from the wastewater, Gas is generated and discharged to the outside.

In the UASB type reaction tank, there is a disadvantage that the inflow wastewater is relatively short in the reaction tank because the inflow wastewater on the bottom surface rises vertically. Accordingly, the influent wastewater has a short time to react with or contact with the anaerobic microbial sludge layer, and the efficiency of removing pollutants is inevitably lowered.

The anaerobic microbial sludge is known to have a specific gravity of about 1.1 to 1.2. The specific gravity is higher than that of water but the anaerobic microbial sludge floats due to the rising flow rate of the inflow wastewater and the rising flow rate of the inflow wastewater is more than a fixed value. have.

In order to prevent the outflow of the anaerobic microbial sludge, the UASB type reactor is forced to set the rising flow rate of the inflow wastewater below a predetermined value. However, since the amount of suspended microbial sludge layer is limited according to the rising flow rate, Thereby causing a problem of lowering the removal efficiency of contaminants due to contact between the sludge and the influent wastewater.

There is a need for an anaerobic granular sludge reaction tank that can solve the existing problems of the UASB type reactor.

10-1048673 (B1), July 12, 2011

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an anaerobic granulation method for maximizing the removal of organic pollutants due to reaction between anaerobic microbial sludge and inflow wastewater by increasing the residence time in the reaction tank for incoming wastewater. And a sludge reaction tank.

It is another object of the present invention to provide an anaerobic granular sludge reaction tank which can increase the residence time of inflow wastewater and prevent the loss of anaerobic microbial sludge by using a structure formed in the reaction tank.

In addition, the present invention provides a method and a system for providing biogas to the anaerobic microbial sludge layer, providing a horizontal flow of the anaerobic microbial sludge layer and using hierarchically structured structures in each wall to enhance contact efficiency between the influent wastewater and the anaerobic microbial sludge and to facilitate granulation of the microbial sludge The present invention provides an anaerobic granular sludge reactor.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

An anaerobic granular sludge reaction tank according to an aspect of the present invention includes a plurality of distributors provided on the bottom surface of a reaction tank for discharging inflow wastewater toward a first wall surface of a reaction tank, And a first baffler for shutting off the discharge of the reaction tank in the vertical direction and inducing the flow toward the second wall surface with respect to the inflow wastewater from the plurality of distributors and the anaerobic microorganism sludge in the reaction tank, A second baffler coupled to the second wall of the first baffler and adapted to block the discharge of the reaction tank in the vertical direction with respect to the incoming wastewater and the anaerobic microbial sludge induced by the first baffler, .

In the above anaerobic granular sludge reaction tank, a device for collecting biogas generated by the contact between the influent wastewater and the anaerobic microbial sludge is connected to the second wall surface at a position higher than the first baffler and lower than the second baffler in the reaction tank 1 gas separator, wherein the sum of the length of the first gas separator and the length of the first baffle is greater than the length of the reactor.

In the above anaerobic granular sludge reaction tank, each of the plurality of distributors has a rectangular shaped discharge hole for discharging the inflow wastewater toward the first wall surface, and the cross sectional area of the discharge hole is equal to the cross sectional area of the inflow waste water circular pipe of the distributor.

In the anaerobic granular sludge reaction tank, the first baffler prevents the anaerobic microbial sludge floating according to the influent wastewater discharged from the plurality of distributors from the outer tank of the reactor, and the biogas generated due to the reaction between the anaerobic microbial sludge and the influent wastewater To the gas separator and to circulate the settled anaerobic microbial sludge to the plurality of distributors.

In the anaerobic granular sludge reaction tank, the first baffler having a plurality of slope shapes inclined with respect to the bottom surface has a circulation hole for circulating the anaerobic microorganism sludge settled at the point where the two slopes meet to a plurality of distributors Or more.

In the above anaerobic granular sludge reaction tank, the second gas separator is connected to the first wall surface at a position higher than the second baffler in the reaction tank and collects the biogas generated by the contact between the inflow wastewater and the anaerobic microbial sludge The sum of the length of the second separator and the length of the second baffler is greater than the length of the reactor and the second gas separator is directed in the direction of the first wall surface by the second baffler, And to collect rising biogas from the location.

The anaerobic granular sludge reaction tank according to the present invention can maximize the removal of organic pollutants due to the reaction between the anaerobic microbial sludge and the inflow wastewater by increasing the residence time of the inflow wastewater in the reaction tank.

In addition, the anaerobic granular sludge reaction tank according to the present invention as described above has the effect of increasing the residence time of the influent wastewater and preventing the loss of the anaerobic microbial sludge by using the structure formed in the reaction tank.

In addition, the anaerobic granular sludge reaction tank according to the present invention provides a horizontal flow to the anaerobic microbial sludge layer and improves the contact efficiency between the influent wastewater and the anaerobic microbial sludge by using a hierarchical structure on each wall surface And to promote the granulation of the microbial sludge.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

1 is a view showing an exemplary configuration of an anaerobic granular sludge reaction tank according to the present invention.
FIG. 2 is a view showing the configuration of distributors installed on the bottom of the reaction tank.
FIG. 3 is a diagram showing a schematic three-dimensional structure of an anaerobic granular sludge reaction tank according to the present invention.
4 is a diagram showing an exemplary flow flow in a reactor of materials including wastewater caused by the internal structure of the anaerobic granular sludge reactor of the present invention.

The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: It can be easily carried out. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing an exemplary structure of an anaerobic granular sludge reaction tank 100 according to the present invention.

The anaerobic granular sludge reaction tank 100 according to the present invention is characterized in that the anaerobic granular sludge reaction tank 100 decomposes and removes contaminated organic substances such as carbohydrates, proteins, and fats remaining in the influent wastewater using anaerobic microorganisms, It is a device that can discharge waste water.

The anaerobic granular sludge reaction tank 100 is provided with a plurality of anaerobic microorganism sludge therein. The anaerobic granular sludge reaction tank 100 decomposes the polluted organic matter of the wastewater by contact between the anaerobic microorganism bacteria and the influent wastewater contained in the anaerobic microorganism sludge, . The resulting biogas can be, for example, CO2 and CH4.

The anaerobic granular sludge reaction tank 100 is configured to purify domestic wastewater or industrial wastewater and to discharge purified water or discharge it to a subsequent wastewater treatment plant.

1, the anaerobic granular sludge reaction tank 100 includes at least one wall 110, a plurality of distributors 120, a first baffler 130, A first gas separator 150, a second gas separator 160 and an outlet weld 170 and pipings 180 for supplying and discharging various gases and wastewater.

The anaerobic granular sludge reaction tank 100 has a shape of a rectangular parallelepiped or a cylindrical shape (a columnar shape) and has wall surfaces 110 for constituting the shape. The wall surfaces 110 of the anaerobic granular sludge reaction tank 100 are divided into six surfaces of Top, Bottom, Left, Right, Front and Rear And may be composed of an upper surface, a lower surface, and an integral surface having a circular cross section between the upper surface and the lower surface. The anaerobic granular sludge reaction tank 100 may have various shapes other than a rectangular parallelepiped shape and a cylindrical shape, and the seating surface, the right side surface, the front side, and the rear side may vary depending on the viewing position and setting.

The wall 110 is made of concrete, steel, etc., and is configured to house various constituent elements therein, temporarily store inflow wastewater, and treat the water by the anaerobic microorganism bacteria and then discharge it to the outside.

The anaerobic granular sludge reaction tank 100 includes a plurality of distributors 120 to supply wastewater flowing through the pipe 180 into the reactor 100.

As shown in FIG. 2, a plurality of distributors 120 are uniformly distributed on the bottom of the reaction tank 100 to discharge the inflow wastewater toward the specific wall surface of the reaction tank 100.

Specifically, each of the distributors 120 may be installed at a certain distance from the other adjacent distributor 120 at the bottom of the reactor 100.

The distributor 120 may have a rectangular-shaped discharge hole 121. The discharge hole 121 can discharge the incoming wastewater in the direction of one wall surface of the reaction tank 100 according to the designed water pressure and flow rate. The discharge holes 121 of all the distributors 120 can discharge the incoming wastewater in the same wall surface direction. For example, the distributors 120 discharge the incoming wastewater horizontally from the bottom toward one wall 110, leading the incoming wastewater to the incoming wastewater flow in a horizontal direction, not perpendicular to the bottom.

The direction of the wall surface to be discharged may be, for example, the direction of the wall surface opposite to the pipe 180 supplying the inflow wastewater. When the reaction tank 100 is a rectangular parallelepiped, the wall surface direction can be specified by a single wall surface 110. However, when the reaction tank 100 is cylindrical, it may represent a part of the entire surface of the cylinder and may be an angle from the center of the bottom surface The direction may be specified.

As can be seen from FIG. 2, the discharge hole 121 of the distributor 120 has a rectangular shape, and the long side of the rectangle is horizontal to the bottom and the short side is perpendicular to the bottom. In addition, the cross-sectional area of the rectangular discharge hole 121 is configured to be equal to the cross-sectional area of the inflow waste water circulation pipe 180 directly connected (directly) to the distributor 120. By using such a structure, the distributors 120 disperse and supply wastewater from the floor bottom to a specific wall surface. Accordingly, the reaction tank 100 can provide a flow below the anaerobic microbial sludge layer, thereby improving the contact efficiency between the anaerobic microbes and the inflow wastewater, thereby improving the treatment efficiency and promoting the granulation of the sludge.

The first baffler 130 is installed in the reaction vessel 100 on the wall surface 110 located at a higher position in the vertical direction than the distributors 120 and is connected to the inflow wastewater discharged from the distributors 120, ) Of the anaerobic microbial sludge and the flow of the biogas generated by the contact between the anaerobic microbial sludge and the anaerobic microbial sludge are controlled according to the hydraulic pressure and the flow rate of the influent wastewater.

The first baffle 130 is fixedly coupled to the wall surface 110 in the direction in which the distributor 120 is discharged and the adjacent wall surfaces 110. The first baffler 130 has a space region in which the first baffler 130 is installed And the anaerobic microbial sludge and biogas in the reaction tank 100 are prevented from being discharged in the vertical direction on the upper surface and the flow is directed in the direction of the other wall surface.

In other words, the first baffler 130 blocks the upward flow of the biogas generated due to the contact reaction between the inflow wastewater and the floating anaerobic microbial sludge, which flows due to the hydraulic pressure and the flow rate of the wastewater, The flow of the flow material can be directed to the wall surface 110 (e.g., the wall surface 110 opposite to the discharge direction of the distributor 120).

The first baffle 130 may be made of a material such as concrete, steel, plastic, or stainless steel to block the flow of the flowing material vertically.

The second baffler 140 is disposed in the reaction vessel 100 in a direction perpendicular to the first baffler 130 in a direction in which the distributor 120 discharges the same, (Fixed) to adjoining wall surfaces 110 so that the biogas produced by the anaerobic microbial sludge and the anaerobic microorganism bacterium and the wastewater from which the flow is induced by the first baffler 130 is discharged in the vertical direction on the upper surface And it is directed toward the other wall surface.

For example, the second baffler 140 is fixed to the wall surface 110 opposite to the wall surface 110 where the first baffler 130 is installed and the adjacent wall surfaces 110 to form the first baffler 130, (E.g., a wall surface 110 that is the same as the discharge direction of the dispenser 120), or the other wall surface 110 in the horizontal direction To another wall surface 110 having a 90 degree angle).

The second baffler 140 may be made of a material such as concrete, steel, plastic, or stainless steel to block the flow of the flowing material in the vertical direction.

The first baffle 130 and the second baffler 140 are fixedly installed on different wall surfaces 110 at different heights so as to provide various functions within the reaction tank 100. The first baffler 130 and the second baffler 140 block the flow of the flow material in the vertical direction and induce a flow of the flow material in the direction of the wall surface 110 in a direction other than the installed (fixed) wall surface.

Accordingly, the first baffler 130 and the second baffler 140 prevent external leakage of the anaerobic microbial sludge floating according to the hydraulic pressure and the flow rate of the influent wastewater, To the gas separators (150, 160) on a space region where the first and second baffles (130, 140) are not installed, so that the residence time of the incoming wastewater in the reaction tank (100) can be increased. Furthermore, the first and second baffles 130 and 140 are configured to circulate the anaerobic microbial sludge, which is settled after float, to the plurality of distributors 120. [

A more detailed physical structure of the baffler 130, 140 will be described with reference to FIG.

The first gas separator 150 is a wall surface in which the second baffler 140 is installed at a position higher than the first baffler 130 and lower than the second baffler 140 in the vertical direction in the reaction tank 100 110) to collect the biogas generated by the contact between the influent wastewater and the anaerobic microbial sludge.

Preferably, the first gas separator 150 is fixed at a higher position than the first baffler 130 so that the flow is directed through the first baffler 130 and the interruption by the first baffler 130 And is configured to collect biogas rising vertically into the void space.

The first gas separator 150 is configured to collect the as much as possible of the biogas that is induced by the first baffler 130 and rises vertically without interruption by the first baffler 130, The length of the first baffler 130 between the wall surface 110 (the wall surface 110 where the first baffle 130 is installed and the wall surface 110 where the second baffle 140 is installed) The sum of the lengths of the first gas separator 150 is configured to be larger than the length of the reaction tank 100 between the both wall surfaces 110 (length of one wall surface in the case of a square cross section, see FIG. 3).

That is, the first gas separator 150 is configured to be partially orbited in the horizontal direction at a position higher than the first baffle 130, so that the space between the first baffler 130 and the opposite wall surface 110 A space that can induce the upward flow because the one-fold plug 130 is not installed).

The first gas separator 150 may include a gas piping 180 exposed to the inside and discharge the biogas to the outside of the reaction tank 100 through the gas piping 180. The biogas released may be CO2 and / or CH4.

The first gas separator 150 may be made of steel, plastic, or stainless steel.

The second gas separator 160 is coupled (fixed) to the wall surface 110 where the first baffler 130 at a higher position than the second baffler 140 is installed in the reaction tank 100, Collect biogas generated (generated) by contact of anaerobic microbial sludge. The second gas separator 160 may be made of steel, plastic, or stainless steel.

Preferably, the second gas separator 160 is fixed at a higher position in the vertical direction than the second baffler 140 such that the flow is directed by the second baffler 140 (and the first baffler 130) And to collect the biogas that vertically rises into space without interruption by the second baffler 140.

The second gas separator 160 is arranged to allow the collecting stream to be collected so that it can collect as much as possible the biogas that is induced by the second baffler 140 and rising vertically without interruption by the second baffler 140. [ Of the second baffler 140 between the opposite wall surfaces 110 (the wall surface 110 where the first baffle 130 is installed and the wall surface 110 where the second baffle 140 is installed) And the length of the second gas separator 160 is greater than the length of the reaction vessel 100 of both wall surfaces 110 (the length of one wall surface in the case of a square cross section, see FIG. 3).

That is, the second gas separator 160 is configured to be partially orbited in the horizontal direction at a position higher than the second baffler 140, so that the space between the second baffler 140 and the opposite wall surface 110 A space for inducing the upward flow due to the absence of the two-fold plug 140).

The second gas separator 160 may include a gas piping 180 exposed to the inside and discharge the biogas to the outside of the reaction tank 100 through the gas piping 180. The biogas released may be CO2 and / or CH4.

The three-dimensional structure of the first baffle 130, the second baffler 140, the first gas separator 150, and the second gas separator 160 will be described in more detail with reference to FIG.

The discharge dresser 170 is a drainage duct for discharging wastewater (water) subjected to the biological treatment through the anaerobic microorganism bacteria against the influent wastewater. According to the present invention, the drainage wearer 170 can drain the anaerobically treated water through diagonal-flow and discharge it out of the reaction tank 100 through the drain pipe. The discharged water can be further purified by an external water treatment plant.

The anaerobic granular sludge reaction tank 100 further includes a plurality of piping 180. The piping 180 connected to the plurality of distributors 120 supplies the wastewater into the reaction tank 100 and the piping 180 connected to the gas separators 150 and 160 supplies the biogas collected by the gas separators 150 and 160 To the outside. The piping 180 connected to the bafflers 130 and 140 is configured to circulate the anaerobic microbial sludge collected by the baffles 130 and 140 into the anaerobic granular sludge reactor 100 through the plurality of distributors 120 do.

A pipe 180 for circulating the sludge settled by the pipe 180 for supplying the wastewater and the sludge settled by the baffles 130 and 140 is connected to the pump 180 for supplying a constant hydraulic pressure and a flow rate The wastewater having a predetermined water pressure and flow rate and the settled sludge are supplied into the reaction tank 100.

FIG. 3 is a view showing a general internal structure of the anaerobic granular sludge reaction tank 100 according to the present invention. 3 is a view showing the three-dimensional configuration of the baffles 130 and 140 and the gas separators 150 and 160 in the anaerobic granular sludge reaction tank 100. As shown in FIG. FIG. 3 shows an example in which the anaerobic granular sludge reaction tank 100 is a rectangular parallelepiped.

As shown in FIG. 3, the first baffle 130 is fixed to the wall surface 110 in a direction in which the distributor 120 at a higher position than the plurality of distributors 120 discharges the wastewater. The first baffler 130 may have a wall surface 110 (e.g., a right side, which may be another wall surface 110, according to a design example) in the discharge direction on a horizontal section, (L 1 is a length smaller than L and longer than 1/2) formed by the front and rear surfaces (front surface and rear surface).

That is, the first baffler 130 is provided with the entirety of the specific wall surface 110 (right side) and the front and rear portions (as long as the length of the l1) so that the wastewater or the like can not be discharged vertically through the specific wall surface 110 The anaerobic microbial sludge floating according to the inflow wastewater and the biogas generated due to the reaction of the anaerobic microbial sludge and the inflow wastewater are prevented from rising in the vertical direction, Leading to a flow in another wall direction (e.g., seating surface).

(For example, a region formed by the entire length L of the right side surface and l1 of the front and rear surfaces) by the first baffler 130 is formed in the horizontal cross section at the position where the first baffle 130 is installed. (For example, an entire length L of the seat surface and a region formed by the front and rear surfaces (L-11)) capable of flowing in the vertical direction such as wastewater, biogas, sludge in the vertical direction And the first baffler 130 induces a flow of various materials in flow to the guidance region.

The bottom structure of the first baffler 130 is preferably configured to be parallel to the bottom surface to direct various float materials to the other wall surface 110 and the top structure of the first baffler 130 may include one or more Has a plurality of slope shapes. The first baffle 130 has a point line (e.g., a valley portion) where two slope shapes meet and has at least one circulation hole 131 on the point line to which it is encountered.

Floating anaerobic microbial sludge can settle. The settled anaerobic microbial sludge can move to the circulation hole 131 through a slope having a slope. The first baffler 130 can discharge the anaerobic microbial sludge settled by the piping 180 connected to the circulation hole 131. The discharged anaerobic microorganism sludge is reintroduced into the plurality of distributors 120 together with the incoming wastewater. The first baffler 130 includes a circulation hole 131 for circulating the microbial sludge settled in the first baffle 130 into the reaction tank 100.

The anaerobic granular sludge reaction tank 100 has a first gas separator 150 at a position higher than the first baffler 130 in the vertical direction. The first gas separator 150 is fixed to the wall surface 110 (for example, the opposite surface 110) in the direction in which the first baffler 130 induces the flow, Collect the gas.

For example, the first gas separator 150 is secured to the left wall surface 110, which is the opposing wall surface 110 of the first baffler 130, and collects as much as possible of the biogas rising vertically through the guidance area And a larger collection area covering the vertical direction phase inducing area so as to be able to cover the vertical induction area.

The first gas separator 150 is installed on the front and rear surfaces starting from the left side wall surface 110 and the left side wall surface 110 which are the opposite wall surfaces 110 of the first baffle 130 and the length L of the left side wall surface 110 And a biogas collecting area (area) equal to the front and rear face length l2. Accordingly, the first gas separator 150 collects the biogas that is induced by the first baffler 130 to the induction region and then vertically rises through the induction region.

On the other hand, the first gas separator 150 and the first baffler 130 are configured to be partially orbited in the horizontal direction. That is, the sum of the length 11 of the first baffle 130 in the horizontal direction and the length 12 of the first gas separator 150 is equal to the length of the wall surface 110 (front and / (L). With this arrangement, the first gas separator 150 can collect all of the generated biogas rising through the induction region as much as possible. Here, l1 is preferably configured to be longer than l2.

The anaerobic granular sludge reaction tank (100) has a second baffler (140) at a position higher than the first gas separator (150). The second baffle 140 is fixedly installed on the wall surface direction induced by the first baffle 130. For example, the second baffler 140 is fixedly mounted on the same wall surface 110 opposite to the first baffler 130 and on which the first gas separator 150 is installed. The second baffler 140 has L * l1 (l1 is smaller than L and less than L / 2) formed by two surfaces (front and rear surfaces) adjacent to the induction direction wall surface 110 Which is larger than the length of the outer circumferential surface.

That is, the second baffler 140 blocks the discharge of the wastewater induced by the first baffler 130 and the floating anaerobic microbial sludge in the vertical direction, and the second baffler 140 is fixed to the wall surface (Which may be, for example, opposite wall 110, another wall 110 depending on the design variant) than the other wall 110 (e.g., seat).

(For example, the entire length L of the seat surface and the area formed by the front and rear surfaces 11) by the second baffler 140 is formed in the horizontal cross section at the position where the second baffler 140 is installed, (For example, the entire length L of the right side surface and the area formed by L-11 of the front and rear surfaces) capable of flowing wastewater, biogas, sludge and the like in the vertical direction and the second baffler (140) induces a flow of various materials into the induction region.

The lower structure of the second baffler 140 is the same as or similar to the lower structure of the first baffler 130. [ The bottom structure of the second baffler 140 is preferably configured to be parallel to the bottom surface to guide the various float materials to the other wall surface 110 and the top structure of the second baffler 140 may include one or more ) Slope shape. The second baffle 140 has a line (e.g., a valley portion) of points where two slope shapes meet and has at least one circulation hole 141 in the location line.

By the two slopes, the anaerobic microbial sludge that has been floating can sink down further. The second baffler 140 can discharge the anaerobic microbial sludge settled by the piping 180 connected to the circulation hole 141. The discharged anaerobic microorganism sludge is reintroduced into the plurality of distributors 120 together with the incoming wastewater. The second baffler 140 has a circulation hole 141 for circulating the microbial sludge settled in the second baffle 140 into the reaction tank 100.

The anaerobic granular sludge reaction tank 100 has a second gas separator 160 at a higher position in the vertical direction than the second baffler 140. The second gas separator 160 is fixed to the wall surface 110 (for example, the right wall surface 110) in the direction in which the second baffler 140 guides the flow, To collect biogas rising vertically.

For example, the second gas separator 160 is secured to the right wall surface 110, which is the wall surface 110 opposite to the second baffler 140, and collects as much of the biogas as it ascends vertically through the guidance area And a larger collection area covering the vertical direction phase inducing area so as to be able to cover the vertical induction area.

The second gas separator 160 is installed on the front and rear surfaces starting from the right wall surface 110 and the right wall surface 110 which are opposite wall surfaces 110 of the second baffle 140 and the length L of the right wall surface 110 And a collecting area (area) equal to the front and rear face length l2. Accordingly, the second gas separator 160 collects the biogas that is induced by the second baffler 140 into the guiding region and then vertically rising through the guiding region.

The second gas separator 160 and the second baffler 140 are configured to be partially orbited in the horizontal direction. That is, the sum of the length 11 of the second baffler 140 in the horizontal direction and the length 12 of the second gas separator 160 is greater than the length L of the horizontal wall surface (front or rear) . With this configuration, the second gas separator 160 can collect all of the generated biogas rising through the induction region as much as possible.

The description of FIG. 3 assumes that the anaerobic granular sludge reaction tank 100 is a rectangular parallelepiped. The case where the anaerobic granular sludge reaction tank 100 is cylindrical has the same or similar structure. For example, the anaerobic granular sludge reaction tank 100 may have a structure in which the first baffler 130 and the second gas separator 160 are fixed in a specific direction in which the distributor 120 discharges the wastewater from the 360 degree cylindrical surface, The second baffle and the first gas separator 150 can be fixed. The first baffler 130 and the second baffler 140 are configured to have a length l1 longer than a radius in a circular sectional area in each direction and have a blocking area of 1/2 or more, The sum of the lengths of the first gas separator 150 is configured to be larger than the length (diameter) of the cylinder. Also, the sum of the lengths of the second baffler 140 and the second gas separator 160 is configured to be larger than the diameter (length) of the cylinder.

The anaerobic granular sludge reaction tank 100 may have another solid shape and may have the inner structure of the reaction tank 100 as shown in this case.

FIG. 4 is a view showing an exemplary flow flow in the reaction tank 100 of materials including wastewater caused by the internal structure of the anaerobic granular sludge reaction tank 100 of the present invention.

First, the anaerobic granular sludge reaction tank 100 has a plurality of anaerobic microorganism sludges of a predetermined size or larger therein, and forms an anaerobic microorganism sludge layer. The anaerobic microbial sludge may have a particle size of about 2-3 mm.

The anaerobic microbial sludge circulating with the wastewater is discharged through the plurality of distributors 120 in accordance with the water pressure and flow rate set in the direction of one wall. The anaerobic microbial sludge layer floats according to the hydraulic pressure and the flow rate and the inflow wastewater and the anaerobic microbial sludge flow into the structure (blocking area) of the one wall 110 and the first baffler 130 (1) to the other (opposite) wall. In this process, the anaerobic microbial sludge contacts the wastewater and the anaerobic microorganism reacts with the wastewater to produce biogas. The generated biogas also moves (flows) in the direction of the other wall by the structure of the first baffler 130.

As it reaches the guiding area, the flowing material can rise in the vertical direction. The biogas is collected by the first gas separator 150. The biogas is collected on the upper side of the first gas separator 150 due to the vertically rising nature and is discharged to the outside of the reaction tank 100 through the gas piping 180 provided on the upper side. The collecting area of the first gas separator 150 is the same or larger than the guiding area and is installed at the same position in the vertical direction with respect to the guiding area so that most of the biogas produced through the reaction can be collected by the first gas separator 150 have.

The floating anaerobic microbial sludge and the wastewater rise or flow through the space next to the first gas separator 150 and the upward flow is blocked by the second baffler 140. The anaerobic microbial sludge and the wastewater are introduced into the second baffler The flow is guided to the wall surface 110 opposite to the wall surface 110 of the first gas separator 150 by the second gas separator 150. In this process, the anaerobic microbial sludge can settle. The anaerobic microbial sludge has a specific gravity higher than that of water, so that the anaerobic microbial sludge may have a higher specific gravity than the water, and may be influenced by the magnitude of the hydraulic pressure and the flow rate or by interference (obstruction, blocking, blockage, friction) by the first baffler 130 and / Can be settled.

The anaerobic microbial sludge settling through the provided slope shape moves by the inclination of the slope into the circulation hole 131 provided at the point (line) where the slope of the first baffler 130 meets. The circulation hole 131 can be connected to the external circulation pipe 180 to recycle the anaerobic microbial sludge settled in the distributor 120.

As it reaches the guiding region formed by the second baffle 140, the flowing material can rise in the vertical direction (see ④). Among them, the residual biogas generated in the flow of (3) is collected by the second gas separator 160. The biogas is collected on the upper side of the second gas separator 160 due to the vertically rising nature and is discharged to the outside of the reaction tank 100 through the gas piping 180 provided on the upper side. The collecting area of the second gas separator 160 is the same or larger than the induction area formed by the second baffler 140 and is installed at the same position in the vertical direction so that most of the biogas produced through the reaction is introduced into the second gas Separator 160 can collect.

The flocculated anaerobic microbial sludge and wastewater flow or flow upward through the space next to the second gas separator 160 (see [5]). In this process, the anaerobic microbial sludge can settle. The anaerobic microbial sludge settling through the provided slope shape is moved by the slope of the slope to the circulation hole 141 provided at the point where the slope of the second baffler 140 meets. The circulation hole 141 may be connected to the external circulation pipe 180 to recycle the anaerobic microbial sludge settled in the distributor 120.

The inflow wastewater treated by the anaerobic microbes is filled into the discharge ware 170 and discharged to the outside through the discharge ware 170.

As shown in FIG. 4, the anaerobic granular sludge reaction tank 100 according to the present invention has two or more baffles 130 and 140, and each of the baffles 130 and 140 has a different wall surface 110, To guide the flow of the flow material to the wall surface 110 in the horizontal direction rather than in the vertical direction. Accordingly, the treatment time of the anaerobic microorganism can be increased by increasing the residence time of the wastewater in the reaction tank 100. The anaerobic granular sludge reaction tank 100 according to the present invention is configured to increase the residence time of the wastewater by causing at least a diagonal flow flow and further promote the granulation of the anaerobic microbial sludge.

In addition, the anaerobic granular sludge reaction tank 100 according to the present invention includes two or more gas separators 150 and 160, and each gas separator has a collection area larger than that of the baffles 130 and 140, And most of the biogas rising vertically through the region is captured.

In addition, the baffler (130, 140) is configured to collect and recycle the anaerobic microbial sludge having two or more slope shapes without sedimenting out.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. The present invention is not limited to the drawings.

100: Anaerobic granule sludge reaction tank
110: wall
120: Dispenser 121: Discharge hole
130: first baffle 131: circulation hole
140: second baffler 141: circulation hole
150: first gas separator 160: second gas separator
170: Exhaust Wear 180: Piping

Claims (6)

A plurality of distributors provided on the bottom surface of the reaction tank for discharging the inflow wastewater toward the first wall surface of the reaction tank;
A first baffler coupled to a first wall surface and a second wall surface adjacent to each other at a position higher than the plurality of distributors in the reaction tank, the inflow wastewater rising from the plurality of distributors, the anaerobic microorganism sludge in the reaction tank and the anaerobic microorganism sludge The flow of the biogas generated by the reaction of the influent wastewater is divided by the length L of the first wall surface and the installation length 11 of the adjacent two wall surfaces, a first baffler for guiding the first baffle toward the second wall surface by the first baffle;
A first bubbler connected to a second wall surface and a second wall surface at a higher position than the first baffler in the reaction tank and collecting the biogas rising through an induction region excluding the blocking region among all the regions on the horizontal cross- Gas separator; And
A second baffler coupled to a second wall surface at a location higher than the first gas separator and to two adjacent wall surfaces in the reaction tank, the flow of the influent wastewater rising through the guidance area and the anaerobic microbial sludge to the second wall surface And a second baffler for guiding in the direction of the first wall surface by a blocking region on the horizontal section of the second baffler formed by the length and the installation length on two adjacent wall surfaces,
The first gas separator discharges the biogas collected through a collecting area larger than the guiding area obliqued with the guiding area in the vertical direction to the outside of the reactor through a gas pipe provided in the first gas separator,
The first baffler has a plurality of slope shapes inclined with respect to a bottom surface and a bottom surface that are horizontal to the bottom surface and one circulation hole for circulating the anaerobic microbial sludge settled at the point where the slopes meet to a plurality of distributors The anaerobic microorganism sludge floating according to the incoming wastewater discharged from the plurality of distributors is prevented from being leaked to the outside of the reactor and the biogas generated by the reaction between the anaerobic microorganism sludge and the influent wastewater is led to the gas separator and the precipitated anaerobic microorganism Wherein the sludge is circulated to the plurality of distributors,
Anaerobic granule sludge reaction tank. delete The method according to claim 1,
Each of the plurality of distributors has a rectangular discharge hole for discharging the inflow wastewater toward the first wall surface,
Sectional area of the discharge hole is equal to the cross-sectional area of the inflow wastewater circular pipe of the distributor,
Anaerobic granule sludge reaction tank. delete delete The method according to claim 1,
Wherein the first baffle is connected to the first wall surface and the adjacent two wall surfaces at a position higher than the second baffler in the reaction tank, and is moved through the induction region excluding the blocking region of the second baffler among the entire region on the horizontal section of the reaction tank, And a second gas separator for collecting the biogas generated by the reaction of the anaerobic microbial sludge,
The second gas separator is connected to the second gas separator through a gas pipe provided inside the second gas separator, and the biogas collected through the collecting area larger than the guiding area is obliqued with the guiding area of the second baffler in the vertical direction, However,
Anaerobic granule sludge reaction tank.

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