KR101026964B1 - Air diffser - Google Patents

Abstract

PURPOSE: An air diffuser is provided to improve the durability and the oxygen transferring efficiency of the air diffuser by preventing the abrasion and the clogging of a through hole due to the contact of mobile microorganism carriers. CONSTITUTION: An air diffuser(100) includes an oxygen supplying tank, a reactor(10), an oxygen supplying pipe(20), an air diffusing pipe(30), and an end plate. The oxygen supplying tank is installed at the outside of the reactor. The reactor includes the oxygen supplying pipe, the air diffusing pipe, and the end plate. The oxygen supplying pipe is in connection with the oxygen supplying tank. The air diffusing pipe is in connection with the oxygen supplying pipe. A plurality of through holes is formed in the longitudinal direction of the air diffusing pipe. A pair of end plates is V-shaped to be in contact with each other.

Description

Air diffuser {air diffser}

The present invention relates to an air diffuser device that has a decisive effect on treatment efficiency and blower power consumption rate in a wastewater treatment plant bioreactor.

In general, the acid apparatus for treating wastewater and wastewater is a device for culturing and propagating microorganisms in a reaction tank so that the microorganisms have a biological effect, thereby decomposing and purifying organic substances in wastewater and wastewater.

In order for the microorganism to reproduce, oxygen is required.

In order to supply oxygen to the microorganisms, a conventional acid generator includes an oxygen supply tank provided outside the reaction tank, an oxygen supply pipe interposed with a blower, one end of which is connected to the oxygen supply tank, and the other end of which extends inside the reaction tank, and An air diffuser having a plurality of through-holes in the longitudinal direction is provided with one end connected to the oxygen supply pipe and the other end blocked.

The conventional acid generator has the above configuration to supply oxygen to the reaction tank and allow the microorganisms to multiply by this oxygen.

In particular, the conventional diffuser is made of EPDM material, the pore contraction occurs due to aging and curing, thereby increasing the ventilation resistance, thereby blocking the plurality of through-holes by the fluidized bed microbial carrier, Damage to the engine to produce a coarse bubble, and also has a problem that causes a problem when the blower stops.

In addition, due to the biological action of the microorganism, in the process of decomposing and purifying sewage, wastewater and sludge, the temperature of the sewage and wastewater in the reactor rises, whereby a temperature difference occurs between the reactor and the oxygen supply pipe. Due to the condensation water is generated in the oxygen supply pipe. As such, when the condensation water gradually accumulates inside the oxygen supply pipe, oxygen is not smoothly supplied into the reaction tank, and thus, the conventional air dispersing device has a problem that the propagation of microorganisms becomes inactive.

The present invention has a problem in solving the above problems.

According to the present invention, a drain nozzle is provided at a downstream end of the oxygen supply pipe, the diffuser is made of SUS material, and a plurality of through-holes are formed in the diffuser in the longitudinal direction. By forming an elongated through hole and allowing the end plate to be detachably mounted while forming a slotted hole in the elongated through hole, and by providing the end plate as a set having various sizes to adjust the size of the slotted hole, Can solve the problem.

The present invention, the acid pipe is made of SUS material, to prevent the through-hole blockage and corrosion damage due to the contact of the fluid microbial carrier can increase the durability and oxygen transfer efficiency of the acid pipe, the drain nozzle in the downstream end of the oxygen supply pipe It is possible to drain the condensation water generated by the temperature difference between the reaction tank and the oxygen supply pipe through the drain nozzle, and to remove the end plate of any one of the end plate set having various sizes in the elongated through hole formed in the diffuser By mounting as much as possible, it provides an effect that can easily match the amount of oxygen supplied to the reactor.

1 is a perspective view showing the diffuser of the present embodiment provided in the reaction tank,
2 is a perspective view showing the diffuser with the endplate removed;
3 is a perspective view of an endplate, and
4 is a view showing that the diffuser and the end plate are combined.

Hereinafter, an diffuser according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 4.

In Fig. 1, the diffuser of this embodiment is indicated by the reference numeral 100.

The air diffuser 100 is conventionally provided with an oxygen supply tank (not shown) provided outside the reaction tank 10, a blower (not shown) is interposed, one end is connected to the oxygen supply tank and the other end is An oxygen supply pipe 20 extending inside the reactor 10 and an SUS diffuser 30 having a plurality of through-holes formed in the longitudinal direction with one end connected to the oxygen supply pipe and the other end blocked. .

In the present embodiment, a plurality of diffusers 30 are provided and connected to both sides of the oxygen supply pipe so as to be distributed at regular intervals along the longitudinal direction of the oxygen supply pipe 20.

The diffuser 30, as shown in FIG. 4, has a rounded cross-section with an upper portion 31 convex upward when viewed from upstream to downstream, and both side walls 32 are standing upright, and in FIG. As shown in the figure, the lower part 33 is shaped to have a triangular cross section in a state where the upper and lower ends of the stem part 33a are in contact with the bottom of the reactor 10.

In addition, triangular through-holes 36 and 36 are formed in the upstream end wall 34 and the downstream end wall 35 of the lower part 33, respectively. The rectangular through-hole 38 is cut out from the lower end of the both sides of the comb side wall 37 to the apex in the state except the both ends of the side walls 37 and extends over the entire length along the longitudinal direction of the two sides of the comb side wall 37. Formed.

A plurality of through holes 39 are formed in both side walls 32 of the diffuser 30 along the longitudinal direction of the diffuser 30.

The other end of the connecting port 40, one end of which is connected to the oxygen supply pipe 20, is connected to the upstream end wall 34 of the upper part 31.

In addition, as shown in FIG. 4, the lower plate 33 is detachably mounted with a set of end plates 50.

The set of end plates 50, as shown in Figures 3 and 4, both ends can be in geometrical contact with the pair of spigot portion (33a) formed in both the upstream and downstream ends. An angle bar having a V-shaped cross section, wherein the bendable step piece in which both longitudinal ends of both the concave side walls 41 are folded back into the longitudinal direction of the concave side wall 41 and toward the inner surface of the concave side wall 41. All of 42 are provided integrally.
Each of the hypotenuse walls 41 of the set of end plates 50 overlaps with the hypotenuse walls 37 of the diffuser 30 so as to cover a portion of the rectangular through hole 38. The inclination direction length h is different so that the area of the opening O may be different.

The step piece 42 is unfolded and folded back when one of the set of end plates 50 is mounted on the lower portion 33 of the diffuser 30 and then folded back. Plate 50 may be detachably mounted to the diffuser (30).

In addition, the oxygen supply pipe 20 includes a drain pipe 21 at a downstream end thereof, one end of which is connected in a flowable manner and the other end thereof extending vertically downward.

The diffuser configured as described above may act as follows.

At the upstream end and the downstream end of the diffuser 30, the lower part has a triangular shape, and the slit opening O is separated from the bottom of the reactor 10 so that oxygen can be supplied in the downward direction and at the same time, the diffuser Not only does not need a separate base for supporting the drain can extend to the oxygen supply pipe 20 vertically downwards by allowing the oxygen supply pipe 20 to be installed at a predetermined interval away from the bottom of the reaction tank (10) The pipe 21 can be provided.

In addition, the diffuser 30 is made of SUS material, thereby preventing through-hole blockage and corrosion damage due to the contact of the fluid microbial carrier, thereby increasing the durability and oxygen transfer efficiency of the diffuser.

In addition, by providing the drain pipe 21 at the downstream end of the oxygen supply pipe 20, it is possible to drain the condensation water generated by the temperature difference between the reaction tank and the oxygen supply pipe through the drain pipe 21.

In addition, the end plate 40 of any one set of end plates that differ only in the oblique direction length of the hypotenuse wall 41 is formed in the diffuser 30 by detachably attaching to the lower part of the diffuser 30. By enabling the adjustment of the opening degree of the slit opening (O), it provides an effect that can easily match the amount of oxygen supply required for the reaction tank (10).

10; Reactor, 20; Oxygen supply pipe, 21; Drain pipe 30; Diffuser, 31; Top, 32; Side walls, 33; Bottom, 33a; Tip, 34; Upstream end wall, 35; Downstream end wall, 36; Triangular through hole, 37; Rainwall, 38; Rectangular through hole, 39; Through hole, 40; Connector, 41; Rainwall, 42; Steps, 50; Endplates, 100; Diffuser, O; Slit opening

Claims (3)

Oxygen supply tank provided outside the reaction tank 10,
An oxygen supply pipe 20 interposed with a blower, one end of which is connected to the oxygen supply tank, and the other end of which extends inside the reactor 10, and
In the diffuser device comprising an diffuser 30 having a plurality of through holes formed in a longitudinal direction with one end connected to the oxygen supply pipe and the other end blocked.
The diffuser 30 is made of SUS material and has a rounded cross section in which the upper part 31 is convex upward when viewed from the upstream to the downstream side, and both side walls 32 are standing upright, and the lower part 33 is It is shaped to have a triangular cross-section in the state having the top portion and the downstream end 33a in contact with the bottom of the reaction tank 10,
Triangular through holes 36 and 36 are formed in the upstream end wall 34 and the downstream end wall 35 of the lower part 33, respectively. A rectangular through-hole 38 is formed to be cut from the bottom of the two side edges 37 to the apex in the state except for both side ends of 37, and extends over the entire length along the longitudinal direction of the two side edges 37. There is,
A plurality of through holes 39 are formed in both side walls 32 of the diffuser 30 along the longitudinal direction of the diffuser 30.
On the lower portion 33, a set of end plates 50 are detachably mounted,
The set of end plates 50 are angle bars each having a V-shaped cross section so that both ends thereof can be geometrically brought into contact with the pair of stem portions 33a formed at the upstream end and the downstream end. All of the bendable step pieces 42 are integrally provided with both ends of the longitudinal side wall 41 being folded back into the longitudinal direction of the side wall 41 and toward the inner surface of the side wall 41.
Each of the hypotenuse walls 41 of the set of end plates 50 overlaps with the hypotenuse walls 37 of the diffuser 30 so as to cover a portion of the rectangular through hole 38. An diffuser device characterized in that the inclination direction length h is different so that the area of the opening O can be different. The diffuser device according to claim 1, wherein the other end of the connection port (40), one end of which is connected to the oxygen supply pipe (20), is connected to the upstream end wall (34) of the upper portion (31). 3. The method according to claim 1 or 2,
The oxygen supply pipe (20) is an air dispersing device, characterized in that the downstream end includes a drain pipe (21), one end of which is connected in a flowable manner and the other end thereof extends vertically downward.

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