JP2002233867A - Process for removing scum layer, spray nozzle for scum layer removal and biological reaction vessel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a process for inhibiting the formation of a scum layer, which inhibits formation of a scum layer in a sewage treatment facilities, also to provide a spray nozzle for removing a scum layer or inhibiting a scum layer from being formed and further to provide a biological reaction vessel provided with the spray nozzle. SOLUTION: This process involves: horizontally jetting washing water so as to form a sectorial flow shape, from a spray nozzle 14 almost immersed below the water surface of a section in which deposition of scum and formation of a scum layer are liable to occur, such as water conduit 2a or biological reaction vessel, in sewage treatment facilities; thereby forming a surface current flowing from the rear side of the spray nozzle 14 in the washing water jetting direction, in such a way that sewage is sucked from the rear side of the spray nozzle 14 by means of the nozzle 14; and breaking the scum with the washing water jetted from the spray nozzle 14, to inhibit any scum layer from being formed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for removing a scum layer in a sewage treatment plant for preventing generation of a scum layer, a spray nozzle for removing or preventing the scum layer, and a biological reaction tank provided with the spray nozzle. Things.

[0002]

2. Description of the Related Art Conventionally, in a sewage treatment plant, as shown in FIG. 5, particles having a high specific gravity, such as earth and sand, in an inflow sewage are first settled and separated in a sand basin 1 and then large floating garbage and foreign substances. Is removed by a screen, and then the sewage is guided to the sedimentation basin 2 through the sewer 2a. In the waterway along the way, in order to prevent anaerobic decay of the sewage, preliminary aeration for blowing air or oil and fat in the sewage is performed. An oil / fat separation operation for floating / separating the component is performed.

The sewage of the sedimentation basin 2 is sent to the aeration tank 3 through the culvert 3a, and further sent from the aeration tank 3 to the final sedimentation basin 4 through the culvert 4a. The sewage flowing into the aeration tank 3 is mixed with the activated sludge mainly composed of microorganisms, and at the same time, oxygen in the air is dissolved by mechanical stirring from the surface of the water, or compressed air is injected as bubbles from the bottom to aerate. After mixing in the tank 3 and microbial decomposition treatment, the mixture is led to the final sedimentation basin 4. Part of the activated sludge settling in the final settling tank 4 is settled and concentrated, and is returned to the settling tank 2 and the aeration tank 3 again. The supernatant water flowing out of the final sedimentation basin 4 is disinfected and drained.

On the other hand, as an example of advanced treatment method of the sewage, there is AO method or _{A 2} O method. FIG. 6 shows a biological reaction tank 5 based on the A ₂ O method. The biological reaction tank 5 includes anaerobic tanks 6 and 7 and an aerobic tank 8 partitioned by a baffle wall 10. The anaerobic tanks 6 and 7 are agitated by the stirrers 6b and 7b, and in the aerobic tank 8, air is sent into the tank by the diffuser 8a. The supernatant water from the sedimentation basin is supplied to the anaerobic tank 6 of the biological reaction tank 5 to decompose organic substances in the sewage by anaerobic digestion by anaerobic bacteria. In addition,
Anaerobic tank 7 may be referred to as an anoxic tank.

[0005]

In the sewage treatment facility shown in FIG. 5, an operation of preliminary aeration for blowing air or an operation of separating fats and oils for floating and separating fat and oily components in the sewage is performed. In addition, floating sludge (floating residue, scum) which is not completely removed together with the sewage flows into the sedimentation basin 2 from the water conduit 2a through the baffle wall 2b. At that time, the scum is deposited on the baffle wall 2b from the headrace 2a to 20 to 5
A scum layer S reaching 0 cm is formed. In the aeration tank 3, air bubbles adhere to the sludge and float. The sludge descends along the baffle wall 4 b from the aeration tank 3 via the water conduit 4 a and flows into the final sedimentation tank 4. Similarly, the scum is deposited on the baffle wall 4b from the headrace 4a to form a scum layer S reaching 20 to 50 cm.

On the other hand, in the biological reaction tank 5 based on the A ₂ O method shown in FIG. 6, sewage flowing from the sedimentation tank flows into the anaerobic tank 6 of the biological reaction tank 5, and the anaerobic tank 6 removes anaerobic organic substances in the sewage. During the anaerobic digestion by bacteria, scum is generated, and the treated water flows downstream from the weir 6a formed by the baffle wall 10, so that the scum is deposited on the weir 6a and its thickness reaches 20 to 50 cm. A scum layer S is formed. The treated water in the anaerobic tank 7 is sent to the aerobic tank 8, and in the anaerobic tank 7, a phenomenon in which a scum layer S is similarly generated on the weir 7 a by the baffle wall 10 is seen.

When the scum layer S is formed, it is usually removed manually. At that time, a nozzle 11 as shown in FIGS. 7A and 7B was used. The nozzle 11 in FIG. 7A has a shape whose tip is narrowed. With this nozzle 11, the scum S could be partially removed, but the whole could not be broken. FIG. 7B
The tip of the nozzle 12 was similarly narrowed, and although the scum layer S could be broken in the vertical direction, the whole could not be broken.

Furthermore, these nozzles have a narrowed tip, and may be blocked by scum, which is not preferable. In addition, the scum layer S can be partially broken, but in order to break all the scum layers S, it is necessary to move the nozzle to another part and perform an artificial operation such as spraying the washing water on the scum layer S. However, there was a problem in workability.
Further, there is a drawback that the washing water sprayed from the nozzles 11 and 12 to the scum layer scatters to the worker, or the workplace is filled with mist and emits a bad smell, and the working environment is deteriorated, resulting in unsanitary condition.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and has been made in consideration of the above-described problems, and is directed to a method for removing a scum layer in a sewage treatment plant, and a spray for removing the scum layer or preventing the generation of a scum layer. The present invention relates to a nozzle and a biological reaction tank provided with the spray nozzle.

[0010]

Means for Solving the Problems The present invention has been made to achieve the above object, and the invention of claim 1 has the following features.
A spray nozzle is substantially buried below the surface of the scum of a sewage system or a biological reaction tank in a sewage treatment facility where scum is likely to accumulate and form a scum layer, and washing water is sprayed in a fan-shaped horizontal direction from the spray nozzle. Then, a surface flow is generated from the rear of the spray nozzle in the spraying direction of the washing water, and the scum flowing into the spray nozzle portion from the rear of the spray nozzle with the surface flow is crushed by the washing water sprayed from the spray nozzle. The removal or generation of a scum layer.

According to the first aspect of the present invention, in the sewage treatment facility including the biological reaction tank, the air is adhered to the organic pollutants and floated by diffusing the inflow sewage.
Decomposition gas such as carbon dioxide, methane gas or ammonia due to decomposition by biological reaction is likely to be generated as scum floating on the sludge adhered to the sludge, the sewage scum generated in such a sewage treatment process through the sewer, sedimentation ponds, When flowing from the aeration tank to the sedimentation tank through the sewer, a scum layer is formed in the sewer or adheres to a weir formed by the baffle wall to easily form a scum layer. Furthermore, in the biological reactor,
When flowing from the anaerobic tank to the anaerobic tank and from the anaerobic tank to the aerobic tank,
A similar thing happens. The cleaning water is sprayed in a fan-shaped horizontal direction from a spray nozzle submerged on the water surface to a portion where such a scum layer is likely to be generated, thereby forcibly generating a surface flow. The scum flows into the spray nozzle portion along with the surface flow, and the scum is broken by the water stream jetted from the spray nozzle to prevent aggregation and prevent its growth. The spray nozzle is disposed, for example, at a position where its open end is submerged in the water surface, or is arranged so that its open end is slightly above the water surface, and most of the nozzles submerge under the water surface. In this way, the surface water is generated by the cleaning water that is sprayed from the nozzle in a fan shape in the horizontal direction.

According to a second aspect of the present invention, the end of the pipe into which the washing water is fed is opened, and the end of the pipe is curved in an arc perpendicular to the axial direction of the pipe. A flow path is formed, and a back side surface of the fan-shaped flow path is curved in an arc shape along the fan-shaped flow path curved in an arc shape,
The washing water sent from the pipe is along the fan-shaped flow path,
A spray nozzle for removing a scum layer, which is ejected in a fan shape in a substantially horizontal direction.

According to the second aspect of the present invention, the spray nozzle forms a fan-shaped flow path curved in an arc shape at right angles, and the back side is curved in an arc shape along the curved arc-shaped fan flow path. In addition, the washing water is jetted in a substantially horizontal direction in a fan shape without being decelerated along the fan-shaped flow path. Since the back side of the fan-shaped flow path is curved in an arc shape, the sewage behind the spray nozzle is pushed forward through the spray nozzle without any resistance along the spray direction of the washing water. As a result, a surface flow is generated. For example, the amount of washing water injected from the nozzle is 30 to 60 liters / min, and preferably 50 to 60 liters / m.
in.

According to a third aspect of the present invention, at least an anaerobic tank and an aerobic tank partitioned by a baffle wall are provided, and treated water in the anaerobic tank is transferred from the anaerobic tank to an adjacent anaerobic tank or aerobic tank. A biological reaction tank that breaks down organic matter contained in sludge with microorganisms so as to flow over the weir of the baffle wall,
Biologically, a spray nozzle is installed below the upstream water surface near the baffle wall to generate a surface flow by injecting washing water in a fan shape in a substantially horizontal direction to prevent or remove the generation of a scum layer. It is a reaction tank.

According to the third aspect of the present invention, in the biological reaction tank in which the anaerobic tank and the anaerobic tank, and the anaerobic tank and the aerobic tank are separated by a baffle wall, the sludge is decomposed using microorganisms. To prevent scum mixed with the overflow water flowing out of the baffle wall by bubbles such as carbon dioxide gas and methane gas sticking to it and growing gradually to form a scum layer The spray water is sprayed from the spray nozzle to the upstream side from the baffle wall to generate a surface flow, and the scum is sucked into the spray nozzle portion by flowing the scum to the upstream side beyond the spray nozzle. In this way, it is possible to prevent the scum layer from growing on the upper end of the baffle wall by crushing with the washing water injected from the spray nozzle.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of a scum layer removing method, a scum layer removing or scum layer preventing spray nozzle and a biological reaction tank according to the present invention will be described below with reference to the drawings.

FIG. 1 schematically shows a sewage treatment facility according to the present invention, and a method for preventing scum layer formation will be described with reference to FIG. In sewage treatment equipment, as shown in FIG.
First, particles having a high specific gravity, such as earth and sand, contained in the incoming sewage are settled and separated in the sand basin 1 to remove large buoyant dust and foreign substances with a screen, and preliminary aeration for blowing air into the sewage, or An oil / fat separation operation for floating / separating the oil / fat component is performed, and the sewage flows down the water conduit 2a, descends along the baffle wall 2b, etc., and is guided to the sedimentation basin 2.

As for the sewage, the sludge contained in the sewage becomes floating sludge (scum) by preliminary aeration and flows into the headrace 2a and the baffle wall 2b. The sewage flows down along the baffle 2b, but the scum is blocked by the baffle 2b,
And it tries to accumulate with its buoyancy. Spray nozzle 14
Is placed in this part. From the spray nozzle 14, the cleaning water is sprayed in a fan shape in the horizontal direction to form a surface flow of sewage. The surface flow is, for example, 1 to 3 c from the water surface.
m means a water stream generated at a depth of up to m. The surface flow generated by injecting the washing water from the spray nozzle 14 can prevent scum from growing and forming a scum layer. The scum prevents the floc (aggregate) from being formed by the washing water injected from the nozzle 14 so as to be sucked into the nozzle 14 along with the surface flow before the scum layer is formed. And sent to the sedimentation basin 2 together with the sewage.

In the sedimentation basin 2, fine suspended solids (sludge) that did not settle in the sand basin 1 settle, and the supernatant water flows into the aeration tank 3 through the water conduit 3a over the weir of the sedimentation basin 2. In the aeration tank 3, an air diffuser 3b is installed, air is sent into the tank, and the sewage is kept aerobic. In the aeration tank 3, organic pollutants in the sewage are biochemically oxidatively decomposed. The sewage treated in the aeration tank 3 flows into the final sedimentation tank 4 through the headrace 4a, flows down the baffle wall 4b, and flows into the final sedimentation tank 4.

In the aeration tank 3, organic pollutants are biodegraded by aerobic bacteria to generate new scum,
The water flows down the headrace 4a and is obstructed by the baffle wall 4b.
4 is provided to prevent scum from accumulating.
The washing water is sprayed in the horizontal direction to forcibly generate a surface flow in the treated water flowing through the headrace 4a. The scum is broken down without being formed by agglomeration due to the injection of the washing water to generate a surface flow, and the scum is sent to the final settling tank 4.

In the present embodiment, a spray nozzle is disposed in a portion of a sewage treatment plant where a scum layer is formed, so that a surface flow is forcibly generated so as to be sucked into the spray nozzle from behind the spray nozzle. so,
This is to prevent the occurrence of scum. The scum layer is also generated in the advanced treatment facility shown in FIG. 2 in addition to the present embodiment.

Next, with reference to FIG. 2, an embodiment of the biological reaction tank provided with the spray nozzle of the present invention will be described. This biological reaction tank shows an example of a processing method generally called an AO method or an A ₂ O method. Biological reaction tank 5 in the same figure
Is composed of anaerobic tanks 6 and 7 and aerobic tank 8 partitioned by baffle wall 10. A spray nozzle 14 is installed on the upstream side of the baffle wall 10. The open end of the spray nozzle 14 is immersed in the water surface or is located slightly above the water surface. In the anaerobic tank 6, the sewage inflow from the sedimentation tank is maintained anaerobically, stirred by the stirrer 6b, and sent to the anaerobic tank 7. In the anaerobic tank 7, the stirrer 7
Stirred at b and maintained anaerobic. Anaerobic tank 6,
In 7, the environment where anaerobic bacteria are likely to live is maintained,
Anaerobic digestion of organic pollutants contained in sewage
Biodegradable. The sewage treated in the anaerobic tank 7 is sent to the aerobic tank 8. In the aerobic tank 8, air is sent from the air diffuser 8a into the tank to be maintained aerobic, and to maintain an environment suitable for aerobic bacteria to inhabit. In the aerobic tank 8, organic pollutants are decomposed by a biological reaction of aerobic bacteria, and the treated water is sent to a final sedimentation basin.

In the anaerobic tanks 6 and 7, methane gas and carbon dioxide gas are generated in the process of decomposing organic substances contained in the inflowing sewage by a biological reaction, and air bubbles due to these gases adhere to the sludge and float. appear. The treated water flows into the weir 6a of the baffle wall 10 together with the scum, and the treated water flows into the anaerobic tank 7. Since the washing water is intermittently jetted from the spray nozzle 14, the scum is crushed so as to be crushed by the surface flow caused by the jetting of the washing water, and the scum is formed by the scum.
The water overflows the weir 6a and flows into the anaerobic tank 7. In the anaerobic tank 7, scum flows over the weir 7a and flows into the aeration tank 8.
In the anaerobic tank 7, the scum is injected intermittently from the spray nozzle 14, and the scum is drawn in the direction of the spray nozzle 14 by the surface flow generated by the injection of the wash water, and the injected wash water is sprayed. Crushed into a weir 7
a, and flows into the aeration tank 8. Thus, weir 6
Since the spray nozzle 14 is provided on the upstream side of the nozzles 7a and 7a, the scum is pulverized by the washing water to be sprayed and flows down to the next stage. The spray nozzle 14 has a nozzle layer below the surface of the water, and a surface flow is formed such that air is not mixed with the cleaning water injected from the nozzle 14.

Next, the spray nozzle for removing scum of the above embodiment will be described with reference to FIGS.

First, an embodiment of the spray nozzle will be described with reference to FIG. 3A and 3B are views showing an embodiment of the spray nozzle of the present invention, wherein FIG. 3A is a side view, FIG. 3B is a front view, and FIG. 3C is a perspective view.
In the figure, the spray nozzle 14 has an open end 15a formed by cutting off the end of the water pipe 15 and forming a portion connected to the water pipe 15 into an open end perpendicular to the axial direction of the water pipe 15. 15a, the fan-shaped flow path 16
Are formed. Both sides of the fan-shaped channel 16 are provided with fan-shaped channels 16 so that the sprayed washing water is not scattered more than necessary.
Are provided on both sides. The back side of the fan-shaped channel 16 is smoothly curved in an arc shape like the front side. The diameter of the water pipe 15 is approximately 8 to 15 cm. Of course, the spray nozzle 14 is formed in the water pipe 15, but the spray nozzle 14 may be attached to the water pipe 15.

Next, scum removal by the spray nozzle 14 will be described with reference to FIG. FIG.
The spray nozzle 14 is provided on the scum layer S, and the cleaning water is sprayed from the spray nozzle 14 in a fan-like shape in a substantially horizontal direction along a fan-shaped flow path 16 curved in an arc shape. The cleaning water is sprayed from the spray nozzle 14 below the surface of the front scum layer S, so that the relatively soft scum is broken. On the other hand, the scum layer S behind the spray nozzle 14 generates a surface flow from the back of the spray nozzle 14 to the front, and along the flow,
The bottom of the scum layer S is broken, and the scum layer S is caused to flow from the rear part of the spray nozzle 14 forward so as to be sucked into the spray nozzle 14. Ultimately, all scum is removed.
The rear part of the spray nozzle 14 is the back surface of the fan-shaped flow path 16 and presents a smooth curve, and the scum behind the curved fan-shaped flow path 16 along the flow of the washing water fed from the water supply pipe 15. , And flows forward without being obstructed by the spray nozzle 14 along a fan-shaped flow.

The spray nozzle 14 is disposed so as to be immersed below the surface of the water, but as shown in FIG.
Explaining with reference to the open end 15a, the position of the open end 15a may be set in a range from the water level W1 to W2. For example, the water level W1 from the open end 15a is in a range of 1 to 2 cm, and the position of the open end 15a from the water level W1 is 1 to 2c.
m.

Accordingly, since the spray nozzle 14 forms a fan-shaped flow path 16 curved in a right angle direction, and the opposite side of the curved fan-shaped flow path 16 is curved, the washing water flows horizontally along the fan-shaped flow path 16. Is sprayed in the direction of the fan and the opposite side of the fan-shaped flow path 16 is curved, so that the water behind the spray nozzle 14 is generated along the spray direction and the water flow is generated forward, so that the surface layer is formed on the water surface into which the nozzle is inserted. Flow occurs.
The scum flows along the surface flow so as to be sucked into the spray nozzle 14, and the scum is pulverized.

FIG. 4B shows a surface flow when the spray nozzle 14 is installed and the washing water is sprayed, and the water behind the spray nozzle 14 is directed forward so as to be sucked into the spray nozzle 14. And spray nozzle 14
A superficial flow is generated along the fan-shaped flow injected from the air.
In addition, as shown in FIG. 4C, in water, a surface flow is generated such that water behind the spray nozzle 14 flows forward across the spray nozzle 14. The surface flow in the depth direction occurs horizontally in the range from the open end 15 a to the lower end of the spray nozzle 14.

On the other hand, when the original water pressure at the time when the washing water is supplied to the water pipe is 2 kg / min, the spray nozzle 14
Is about 50 liter / min. If the amount of water injected from the spray nozzle 14 is set in a range of, for example, 40 to 55 liters / min,
The effect of sufficiently removing the scum layer and breaking the scum aggregate is exhibited.

The water sprayed from the spray nozzle 14 is washing water, but is not limited to this, and the treated water or the treated water at the subsequent stage may be used.

[0032]

As described above, according to the present invention, in a sewage treatment plant including a biological reaction tank, a surface flow is forcibly generated in a portion where a scum layer is likely to be generated, and the surface flow is sprayed from a spray nozzle. Crushing the scum with the flowing water,
By inhibiting the growth, there is an advantage that the formation of the scum layer can be prevented.

Further, according to the present invention, the spray nozzle is opened, and the washing water sprayed from the nozzle is sprayed in a fan-shaped horizontal direction without receiving resistance, and is curved in an arc shape. It is jetted horizontally through the fan-shaped flow path, and the back surface of the nozzle is also curved in an arc shape along the fan-shaped flow path. Easy to occur. The scum flows along the surface flow so as to be sucked into the nozzle, and is washed by the washing water injected from the nozzle.
There is the advantage that scum can be prevented from forming aggregates.

Further, according to the present invention, in the anaerobic tank of the biological reaction tank, the organic pollutants contained in the sewage are decomposed by the anaerobic bacteria, and the carbon dioxide gas and methane gas generated at that time adhere to the sludge. The scum layer is formed by installing a spray nozzle on the upstream side of the weir above the baffle wall that separates the anaerobic tank and the anaerobic tank or the anaerobic tank and the aerobic tank. Can be prevented.

[Brief description of the drawings]

FIG. 1 is a diagram showing a sewage treatment flow for explaining one embodiment of a scum layer generation prevention method for preventing generation of a scum layer in a sewage treatment facility according to the present invention.

FIG. 2 is a schematic view showing a biological reaction tank according to the present invention.

FIG. 3 is a view showing one embodiment of a spray nozzle of the present invention, wherein (a) is a side view, (b) is a front view,
(C) is a perspective view thereof.

4A is a side view for explaining removal of a scum layer in a spray nozzle according to the present invention, FIG. 4B is a top view showing a surface flow, and FIG. 4C is a side view of the spray nozzle. FIG.

FIG. 5 is a diagram showing a sewage treatment flow for explaining generation of a scum layer in a conventional sewage treatment facility.

FIG. 6 is a side view for explaining generation of a scum layer in a conventional biological reaction tank.

FIG. 7 is an explanatory diagram for explaining removal of a scum layer by a conventional spray nozzle.

[Explanation of symbols]

 Reference Signs List 1 sedimentation basin 2 sedimentation basin 2a, 3a headrace 2b, 4b baffle wall 3 aeration tank 3b aeration device 5 biological reaction tank 6,7 anaerobic tank 8 aerobic tank 13 pump 14 spray nozzle

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Tsutomu Horikoshi 2-2-1 Nishi-Shinjuku, Shinjuku-ku, Tokyo F-term in Tokyo Metropolitan Sewerage Bureau 2D063 DB01 DB05 DB08 4D040 BB51 4D051 AA01 AB03 CA11 CA22 DD08 DD25

Claims (3)

[Claims] 1. A spray nozzle is substantially buried under a surface of a scum of a sewage treatment plant or a biological reaction tank where a scum layer is likely to be formed and a scum layer is easily formed in a sewage treatment plant. Inject in the horizontal direction, to generate a surface flow in the spray direction of the wash water from behind the spray nozzle,
Scum layer removal, wherein scum flowing into the spray nozzle portion from behind the spray nozzle along with the surface flow is crushed by washing water jetted from the spray nozzle to prevent removal or generation of a scum layer. Method. 2. An end of a pipe into which the washing water is fed is opened, and a fan-shaped flow path curved in a direction perpendicular to the axial direction of the pipe is formed at the end,
And the back side surface of the fan-shaped flow path is curved in an arc shape along the fan-shaped flow path curved in an arc shape, and the washing water fed from the pipe is fan-shaped in a substantially horizontal direction along the fan-shaped flow path. A spray nozzle for removing a scum layer, which is sprayed onto a scum layer. 3. An anaerobic tank and an aerobic tank partitioned by a baffle wall are provided at least, and treated water in the anaerobic tank passes over a weir of the baffle wall from the anaerobic tank to an adjacent anaerobic tank or aerobic tank. A biological reaction tank that decomposes organic matter contained in sludge with microorganisms so that it flows down and flows in, and the cleaning water is sprayed in a substantially horizontal direction in a fan shape below the upstream water surface in the vicinity of the baffle wall. A biological reaction tank provided with a spray nozzle for generating a flow and preventing or removing generation of a scum layer.